Chip assembling system
1. A chip assembly system, comprising: the device comprises a control device, chip feeding equipment, chip handle assembling equipment and assembling equipment of a chip cup and a chip box, wherein the chip feeding equipment, the chip handle assembling equipment and the assembling equipment of the chip cup and the chip box are respectively in communication connection with the control device;
the control device controls the chip feeding equipment to complete chip feeding and transfers the chip to the chip handle assembling equipment;
the control device controls the chip handle feeding device to feed the chip handles;
the control device controls the assembling equipment of the chip cup and the chip box to place the chip cup in the chip box;
the control device controls the chip handle assembling equipment to pick up the chip handle from the chip handle feeding equipment so as to assemble the chip handle on the chip, and the assembled chip and the chip handle are transferred into the chip cup of the chip box of the chip cup and chip box assembling equipment.
2. The chip assembly system according to claim 1, wherein the chip loading apparatus comprises: the device comprises a first transfer device, a feeding device, a direction detection device, a direction adjusting device and a chip feeding device, wherein the first transfer device, the feeding device, the direction detection device, the direction adjusting device and the chip feeding device are respectively in communication connection with the control device;
the first transfer device comprises a first transfer disc and a plurality of first carrier mechanisms, wherein a feeding station, a direction detection station, a direction adjusting station and a feeding station are preset in sequence along the first transfer disc, the first carrier mechanisms are arranged at intervals along the periphery of the first transfer disc and are used for bearing chips, and the control device controls the first transfer disc to operate so that the first carrier mechanisms can be in reciprocating motion between the preset stations;
the feeding device is arranged at the feeding station, and the control device controls the feeding device to place the chip on the first carrier mechanism which flows to the feeding station;
after feeding is finished, the first transfer device transfers the chip flow to the direction detection station; the direction detection device is arranged at the direction detection station, and is used for detecting whether the installation direction of the chip flowing to the direction detection station on the first carrier mechanism is the same as the preset direction or not under the control of the control device;
after the detection of the installation direction of the chip is finished, the first transfer device transfers the chip flow to the direction adjusting station; the direction adjusting device is arranged at the direction adjusting station, and the mounting direction of the chip which is transferred to the direction adjusting station and is different from the preset direction is adjusted through the control of the control device;
after the adjustment of the installation direction of the chips is completed, the first transfer device transfers the chips to the feeding station; the chip feeding device is arranged at the feeding station, and the chips which are transferred to the feeding station are transferred to the chip handle assembling equipment under the control of the control device.
3. The chip assembly system according to claim 1, wherein the chip handle feeding apparatus comprises: the chip handle feeding device, the chip handle transferring device, the chip handle rotating device and the chip handle identifying device are respectively in communication connection with the control device;
the chip handle feeding device is used for containing the chip handles and sending the chip handles out under the control of the control device;
the chip handle transferring device is provided with a receiving station and a sending station, and the control device controls the chip handle transferring device to pick up the chip handles sent out by the chip handle feeding device at the receiving station and transfer the chip handles to the sending station;
the chip handle rotating device is arranged at the delivery station of the chip handle transferring device in a proximity mode, and the control device controls the chip handle rotating device to pick up a chip handle from the delivery station of the chip handle transferring device and turn the chip handle by a preset angle;
the chip handle identification device is arranged adjacent to the chip handle rotating device, and the control device controls the chip handle identification device to identify the direction of a chip handle on the chip handle rotating device.
4. The chip assembly system according to claim 3, wherein the chip handle transferring device comprises a fourth guide rail, a first driving mechanism, a first carrying mechanism and a chip handle transferring mechanism, and the first driving mechanism and the chip handle transferring mechanism are respectively in communication connection with the control device;
the first bearing mechanism is arranged on the fourth guide rail, the chip handle transferring mechanism is arranged on the first bearing mechanism, the first driving mechanism is connected with the first bearing mechanism to drive the first bearing mechanism and the chip handle transferring mechanism to move on the fourth guide rail, and the control device controls the first bearing mechanism to receive the chip handle from a receiving station of the chip handle transferring device and send the chip handle out from the chip handle transferring mechanism at a sending-out station.
5. The chip assembly system according to claim 4, wherein the chip handle transfer mechanism includes a chip handle horizontal pushing cylinder and a pushing block, the chip handle horizontal pushing cylinder is in communication connection with the control device, the chip handle horizontal pushing cylinder is disposed on the first carrying mechanism, the chip handle horizontal pushing cylinder is connected with the pushing block to drive the pushing block to extend and retract in a direction of the sending station at the sending station, and when the pushing block extends towards the sending station, the pushing block sends out the chip handle on the first carrying mechanism.
6. The chip assembly system according to claim 5, wherein the first carrier mechanism is provided with a receiving slot for receiving the chip handle, the pushing block has a pushing portion, the pushing portion of the pushing block is received in the receiving slot of the first carrier mechanism, and the pushing portion of the pushing block is used for pushing and delivering the chip handle out of the receiving slot of the first carrier mechanism.
7. The chip assembly system according to claim 1, wherein the chip handle assembly apparatus comprises: the second transfer device, the pre-installation device, the chip handle assembly device and the chip handle blanking device are respectively in communication connection with the control device;
the second transfer device comprises a second transfer disc and a plurality of second carrier mechanisms, a feeding station, a pre-assembling station, an assembling station and a discharging station are preset in sequence along the second transfer disc, the plurality of second carrier mechanisms are arranged at intervals along the periphery of the second transfer disc and are used for bearing chips, and the control device controls the second transfer disc to operate so that the second carrier mechanisms can be in reciprocating flow between the preset stations;
the control device controls the chip feeding equipment to place the chip on the second carrier mechanism which is transferred to the feeding station in a flowing mode;
after the loading is finished, the second transfer device transfers the chip to a preassembly station, the preassembly device is arranged at the preassembly station, and the chip handle is picked up from the chip handle feeding device and preassembled at one end of the chip transferred to the loading station by the control of the control device;
after the preassembly of the chip handle is completed, the second transfer device transfers the chip and the chip handle to an assembly station, the chip handle assembly device is arranged at the assembly station, and the chip handle transferred to the assembly station are assembled under the control of the control device;
after the equipment of completion chip and chip handle, unloading station department is circulated with chip and chip handle to the second transfer device, chip handle unloader sets up in unloading station department, through controlling means's control, will circulate the chip and the chip handle of unloading station department and shift to in the chip cup of the chip box of the equipment of chip cup and chip box.
8. The chip assembly system of claim 7, wherein the second carrier mechanism comprises: the clamping device comprises a fixed block, a driving block, a resetting piece, a first clamping piece and a second clamping piece;
the fixed block is arranged on the periphery of the second transfer disc, a first containing part is arranged on the top surface of the fixed block, a second containing part is arranged on the side surface of the fixed block, and the first containing part and the second containing part of the fixed block are communicated;
the driving block comprises a first end and a second end which are opposite, the first end of the driving block is accommodated in the second accommodating part of the fixed block, the second end of the driving block is positioned outside the driving block, the resetting piece is arranged in the second accommodating part of the fixed block, and when the driving block moves into the second accommodating part of the fixed block, the resetting piece generates an acting force for driving the driving block to reset;
the lower end of the first clamping piece and the lower end of the second clamping piece are respectively arranged in a first containing part of the driving block, when the driving block moves towards a second containing part of the fixed block, the driving block drives the first clamping piece and the second clamping piece to be separated, and when the driving block moves back to the second containing part of the fixed block, the driving block drives the first clamping piece and the second clamping piece to be close to each other and clamps a chip between the first clamping piece and the second clamping piece;
the second transfer device further comprises a driving mechanism, the driving mechanism is in communication connection with the control device, and the control device controls the driving mechanism to drive the driving block to move into the second accommodating portion of the fixed block.
9. The chip assembly system according to claim 8, wherein a first receiving portion and a second receiving portion are provided on a top surface of the driving block;
the first clamping piece comprises a first clamping block and a first guide shaft, the upper end of the first guide shaft is connected with the lower end of the first clamping block, and the lower end of the first guide shaft is accommodated in the first accommodating part of the driving block; the second clamping piece comprises a second clamping block and a second guide shaft, the upper end of the second guide shaft is connected with the lower end of the second clamping block, and the lower end of the second guide shaft is accommodated in the second accommodating part of the driving block.
10. The chip assembly system according to claim 9, wherein the first receiving portion is a bar-shaped hole or a bar-shaped groove, the second receiving portion is a bar-shaped hole or a bar-shaped groove, and the first receiving portion and the second receiving portion are in a splayed structure with an opening facing the driving mechanism.
11. The chip assembly system according to claim 7, wherein the chip handle assembly equipment further comprises a defect detection device, the defect detection device is in communication connection with the control device, the preset station further comprises a detection station located between the assembly station and the blanking station, after the assembly of the chip and the chip handle is completed, the second transfer device transfers the chip and the chip handle to the detection station, the defect detection device is arranged at the detection station, and whether the chip and the chip handle transferred to the detection station have defects or not is detected under the control of the control device.
12. The chip assembly system of claim 7, wherein the preassembly apparatus comprises: the pre-assembling mechanical arm and the pre-assembling mechanism are respectively in communication connection with the control device;
the pre-installation mechanism comprises a pre-installation support, a chip handle bearing assembly, a chip handle transfer assembly and a press-fitting assembly, the pre-installation support is arranged at a pre-installation station, the chip handle bearing assembly is arranged on the pre-installation support in a lifting mode, the chip handle transfer assembly and the press-fitting assembly are arranged on the chip handle bearing assembly, the control device controls the pre-installation manipulator to pick up a chip handle from the chip handle feeding device and place the chip handle on the chip handle transfer assembly, the control device controls the chip handle bearing assembly to drive the chip handle transfer assembly to move to the position above the second carrier mechanism, and the control device controls the press-fitting assembly to press-fit the chip handle on the chip handle transfer assembly at one end of a chip of the second carrier mechanism.
13. The chip assembly system according to claim 1, wherein the chip cup and chip box assembling apparatus comprises: a chip box feeding device, a chip box carrying device, a chip cup feeding device and a chip cup assembling device;
the chip box feeding device comprises: a chip box feeding mechanism, a chip box turnover mechanism and a chip box transferring mechanism, wherein the chip box turnover mechanism and the chip box transferring mechanism are respectively in communication connection with the control device, the chip box feeding mechanism stores a plurality of chip boxes for feeding the chip boxes, the chip box transferring mechanism is arranged adjacent to the chip box turning mechanism of the chip box feeding mechanism so as to pick up the chip boxes from the chip box feeding mechanism and place the chip boxes on the chip box turning mechanism under the control of the control device, the control device controls the chip box turnover mechanism to switch the placing direction of the chip box, after the chip box is switched, the control device controls the chip box transferring mechanism to pick up the chip box with the placement direction converted from the chip box overturning mechanism and place the chip box on the chip box carrying device;
the chip cup feeding device comprises: the chip cup feeding mechanism is in communication connection with the control device and is used for sending out the chip cups;
the chip cup assembling device is in communication connection with the control device, and the chip cup assembling device is arranged close to the chip cup feeding device and the chip box carrying device so as to pick up the chip cup from the chip cup feeding device under the control of the control device and place the chip cup in a chip box of the chip box carrying device.
14. The chip assembly system according to claim 13, wherein the chip cup feeding device further comprises a chip cup grouping mechanism, the chip cup grouping mechanism is communicatively connected with the control device, the chip cup feeding mechanism is connected with the chip cup grouping mechanism to send out chip cups to the chip cup grouping mechanism, the control device controls the chip cup grouping mechanism to group and arrange the chip cups, and the chip cup assembly device is arranged adjacent to the chip cup grouping mechanism to pick up the grouped chip cups from the chip cup grouping mechanism and place the chip cups in the chip boxes under the control of the control device.
15. The chip assembling system according to claim 14, wherein the chip cup grouping mechanism comprises a chip cup transferring assembly and a chip cup grouping assembly, the chip cup transferring assembly is communicatively connected to the control device, the chip cup transferring assembly is connected to the chip cup feeding mechanism and receives the chip cups fed by the chip cup feeding mechanism, the chip cup grouping assembly is provided with at least one chip cup accommodating portion, the control device controls the chip cup transferring assembly to transfer the chip cups into the chip cup accommodating portions of the chip cup grouping assembly, and the control device controls the chip cup assembling device to pick up the chip cups from the chip cup grouping assembly and place the chip cups in the chip boxes.
16. The chip assembling system according to claim 13, wherein the chip cup assembling apparatus comprises a chip cup picking assembly, a chip cup transferring support, a chip cup translating guide rail, a chip cup translating driving assembly, a chip cup lifting guide rail and a chip cup lifting driving assembly, the chip cup picking assembly, the chip cup translating driving assembly and the chip cup lifting driving assembly are respectively in communication connection with the control apparatus, the chip cup translating guide rail is disposed on the chip cup transferring support, the chip cup lifting guide rail is disposed on the chip cup translating guide rail, the chip cup picking assembly is disposed on the chip cup lifting guide rail, the control apparatus controls the chip cup translating driving assembly to drive the chip cup lifting guide rail to move along the chip cup translating guide rail, and the control apparatus controls the chip cup lifting driving assembly to drive the chip cup picking assembly to move along the chip cup lifting guide rail .
17. The chip assembly system of claim 13, wherein the chip box feeding mechanism comprises a first sensing device, a jacking assembly and at least one chip box feeding cartridge clip, the first sensing device and the jacking assembly are respectively in communication connection with the control device, a plurality of stacked chip boxes are stored in the chip box feeding cartridge clip, the control device controls the first sensing device to sense whether a chip box is arranged on the top end of the chip box feeding cartridge clip or not, the jacking assembly is arranged below the chip box feeding cartridge clip, and the control device controls the jacking assembly to jack up the chip boxes in the chip box feeding cartridge clip so that the chip boxes can move to the top end of the chip box feeding cartridge clip.
18. The chip assembly system of claim 13, wherein the chip box turning mechanism comprises a turning support, a turning assembly and a turning driving mechanism, the turning driving mechanism is in communication with the control device, the turning assembly and the turning driving mechanism are disposed on the turning support, the chip box transferring mechanism picks up a chip box from the chip box feeding mechanism and then places the chip box on the turning assembly, and the control device controls the turning driving mechanism to connect the turning assembly to drive the turning assembly and the chip box on the turning assembly to turn.
19. The chip assembly system according to claim 1, further comprising a labeling device, wherein the labeling device is in communication with the control device, the labeling device is disposed adjacent to the chip cup and chip box assembly device, the chip cup and chip box assembly device transfers the chip box with the chip, the chip handle and the chip cup to the labeling device, and the control device controls the labeling device to attach a label to the chip box.
20. The chip assembly system according to claim 19, wherein the labeling apparatus comprises: the labeling and conveying device, the first labeling device and the second labeling device are respectively in communication connection with the control device;
the control device controls the labeling and carrying device to drive the chip box to move to a first labeling station and a second labeling station;
the first labeling device comprises: the first label transferring mechanism and the first labeling mechanism are respectively in communication connection with the control device, the first label transferring mechanism is arranged adjacent to the first label transferring mechanism to pick up a first label from the first label feeding mechanism under the control of the control device, the first labeling mechanism is arranged adjacent to the first label transferring mechanism to pick up the first label from the first label transferring mechanism under the control of the control device, and the control device controls the first labeling mechanism to attach the first label to a chip box moving to a first labeling station;
the second labeling device comprises: second label feed mechanism, second label transfer mechanism and second labeller construct, second label transfer mechanism with second labeller constructs respectively with controlling means communication connection, second label transfer mechanism with the adjacent setting of second label feed mechanism in order to follow under the controlling means control second label feed mechanism picks up the second label, second labeller construct with the adjacent setting of second label transfer mechanism in order to follow under the controlling means control pick up the second label on the second label transfer mechanism, controlling means control second labeller constructs with the attached second label on the chip box that removes to the second labeller station.
Background
With the development of molecular biology theory and technology, the chip technology has the advantages of high throughput, diversity, miniaturization and automation in the aspect of detection. In the molecular detection of various pathogens, detection is often performed against genes of the pathogen. The chip technology can perform qualitative and quantitative analysis on RNA and DNA of various pathogens, thereby helping a diagnostician to determine the types of diseases and the infection degrees of the diseases. Chip technology therefore plays an increasingly important role in the diagnosis of infectious diseases and the screening of pathogens.
The existing chip assembly process needs to assemble a plurality of structures such as a chip, a chip handle and a chip cup into a whole, however, the assembly process mostly depends on manual work, the working efficiency is low, and the requirement of fast-beat production cannot be met.
Disclosure of Invention
An object of this application is to provide a chip package assembly, and this chip package assembly work efficiency is high, and degree of automation is high, can satisfy the requirement of fast beat production.
The purpose of the application is realized by adopting the following technical scheme:
a chip assembly system, comprising: the device comprises a control device, chip feeding equipment, chip handle assembling equipment and assembling equipment of a chip cup and a chip box, wherein the chip feeding equipment, the chip handle assembling equipment and the assembling equipment of the chip cup and the chip box are respectively in communication connection with the control device; the chip feeding equipment is preferably arranged adjacent to the chip handle assembling equipment, and the control device controls the chip feeding equipment to complete chip feeding and transfer the chip to the chip handle assembling equipment; the chip handle feeding device is preferably arranged adjacent to the chip handle assembling device, and the control device controls the chip handle feeding device to feed the chip handles; the assembling equipment of the chip cup and the chip box is preferably arranged adjacent to the assembling equipment of the chip handle, and the control device controls the assembling equipment of the chip cup and the chip box to place the chip cup in the chip box; the control device controls the chip handle assembling equipment to pick up the chip handle from the chip handle feeding equipment so as to assemble the chip handle on the chip, and the assembled chip and the chip handle are transferred into the chip cup of the chip box of the chip cup and chip box assembling equipment.
Through the chip assembly system that this application provided, can bring following at least one beneficial effect:
in the chip assembling system, the chip handle can be assembled on the chip by arranging the control device, the chip feeding equipment, the chip handle assembling equipment and the assembling equipment of the chip cup and the chip box, and the assembled chip handle are placed in the chip cup of the chip box, so that the assembling of the chip, the chip handle, the chip cup and the chip box is realized.
Drawings
The present application is further described below with reference to the drawings and examples.
Fig. 1 is a schematic structural diagram of a chip assembly system according to an embodiment of the present disclosure;
fig. 2 is a schematic structural diagram of a chip feeding apparatus provided in an embodiment of the present application;
fig. 3 is a schematic structural diagram of a chip provided in an embodiment of the present application;
fig. 4 is a schematic structural diagram of a first transfer device provided in an embodiment of the present application;
FIG. 5 is a schematic structural diagram of a chip handle feeding device according to an embodiment of the present disclosure;
FIG. 6 is a schematic structural diagram of a chip handle according to an embodiment of the present disclosure;
fig. 7 is an enlarged view of a portion S in fig. 5;
FIG. 8 is a schematic structural diagram of a chip handle rotating apparatus provided in an embodiment of the present application;
FIG. 9 is a schematic structural diagram of another chip handle rotating apparatus provided in the embodiments of the present application;
FIG. 10 is a schematic structural diagram of a chip handle assembling apparatus provided in an embodiment of the present application;
FIG. 11 is a schematic structural diagram of a second transfer device provided in an embodiment of the present application;
fig. 12 is a schematic structural diagram of a second carrier mechanism according to an embodiment of the present disclosure;
fig. 13 is an exploded view of a second carrier mechanism according to an embodiment of the present disclosure;
FIG. 14 is a schematic diagram of a preassembly mechanism according to an embodiment of the present disclosure;
FIG. 15 is a schematic structural diagram of an assembly apparatus provided in an embodiment of the present application;
fig. 16 is a schematic structural diagram of a blanking driving mechanism provided in an embodiment of the present application;
FIG. 17 is a schematic structural view of an apparatus for assembling a chip cup and a chip cartridge according to an embodiment of the present disclosure;
FIG. 18 is a schematic structural diagram of a chip cup provided in an embodiment of the present application;
fig. 19 is a schematic structural diagram of a chip box according to an embodiment of the present disclosure;
fig. 20 is a schematic structural diagram of a chip box feeding device provided in an embodiment of the present application;
FIG. 21 is a schematic structural view of a feeding device for chip cups according to an embodiment of the present disclosure;
fig. 22 is a schematic structural diagram of a chip cup assembly apparatus according to an embodiment of the present disclosure;
fig. 23 is a schematic structural diagram of a chip box feeding mechanism provided in an embodiment of the present application;
fig. 24 is a schematic structural diagram of a chip box overturning mechanism provided in an embodiment of the present application;
fig. 25 is a schematic structural diagram of a chip box handling apparatus according to an embodiment of the present disclosure;
fig. 26 is a schematic structural diagram of a labeling apparatus provided in an embodiment of the present application;
fig. 27 is a schematic structural view of a first labeling device according to an embodiment of the present application;
fig. 28 is a schematic structural view of a first labeling mechanism according to an embodiment of the present application;
fig. 29 is an angular schematic view of a second labeling device according to the present embodiment;
fig. 30 is a schematic view of a second labeling device according to another angle in the embodiment of the present application;
fig. 31 is a schematic structural view of a labeling and conveying device according to an embodiment of the present application.
Detailed Description
The present application is further described with reference to the accompanying drawings and the detailed description, and it should be noted that, in the present application, the embodiments or technical features described below may be arbitrarily combined to form a new embodiment without conflict.
Referring to fig. 1, an embodiment of the present application provides a chip assembly system, including: the device comprises a control device, a chip feeding device 1, a chip handle feeding device 2, a chip handle assembling device 3 and a chip cup and chip box assembling device 4, wherein the chip feeding device 1, the chip handle feeding device 2, the chip handle assembling device 3 and the chip cup and chip box assembling device 4 are respectively in communication connection with the control device.
The chip feeding device 1 is preferably arranged adjacent to the chip handle assembling device 3, and the control device controls the chip feeding device 1 to complete chip feeding and transfer the chips to the chip handle assembling device 3.
The chip handle feeding device 2 is preferably arranged adjacent to the chip handle assembling device 3, and the control device controls the chip handle feeding device 2 to feed the chip handles.
The assembling equipment 4 of the chip cup and the chip box is preferably arranged adjacent to the chip handle assembling equipment 3, and the control device controls the assembling equipment 4 of the chip cup and the chip box to place the chip cup in the chip box.
The control device controls the chip handle assembling device 3 to pick up the chip handles from the chip handle feeding device 2 to assemble the chip handles on the chips, and transfers the assembled chips and chip handles to the chip cups of the chip boxes of the chip cup and chip box assembling device 4.
The control device may be any suitable computing device, such as a personal computer, a server, a Programmable Logic Controller (PLC), a single chip, or an integrated computer device, and has functions of receiving information and sending control commands, and the control device may control each device to perform corresponding actions through wired communication or wireless communication, so as to complete the assembly of the chip, the chip handle, the chip cup, and the chip box.
Therefore, by arranging the control device, the chip feeding device 1, the chip handle feeding device 2, the chip handle assembling device 3 and the chip cup and chip box assembling device 4, the chip handle can be assembled on the chip, and the assembled chip handle are placed in the chip cup of the chip box, so that the chip, the chip handle, the chip cup and the chip box are assembled.
In a specific embodiment, the chip assembly system further comprises a labeling device 5, the labeling device 5 is in communication connection with the control device, the labeling device 5 is arranged adjacent to the chip cup and chip box assembly device 4, the chip cup and chip box assembly device 4 transfers a chip box with a chip, a chip handle and a chip cup to the labeling device 5, and the control device controls the labeling device 5 to attach a label to the chip box.
From this, treat that the equipment 4 of chip cup and chip box accomplishes the equipment back to chip, chip handle, chip cup and chip box, can utilize and paste mark equipment 5 and attach the label on the chip box to the realization pastes the mark to the automation of chip package spare, and work efficiency is high.
The structures of the chip feeding device 1, the chip handle feeding device 2, the chip handle assembling device 3, the chip cup and box assembling device 4, and the labeling device 5 according to the embodiment of the present application will be described in detail below with reference to the accompanying drawings.
Referring to fig. 2 to 12, the chip feeding apparatus 1 includes: the device comprises a first transfer device 15, a feeding device 11, a direction detection device 12, a direction adjusting device 13 and a chip feeding device 14, wherein the first transfer device 15, the feeding device 11, the direction detection device 12, the direction adjusting device 13 and the chip feeding device 14 are respectively in communication connection with the control device.
First transfer device 15 includes first transport disc 152 and a plurality of first carrier mechanism 151, follows feeding station, direction detection station, direction adjustment station and pay-off station have been preset in proper order to first transport disc 152, a plurality of first carrier mechanism 151 are followed first transport disc 152 periphery interval sets up, first carrier mechanism 151 is used for bearing the chip, controlling means control first transport disc 152 operates so that first carrier mechanism 151 reciprocates to circulate between predetermined station.
The feeding device 11 is disposed at the feeding station, and the control device controls the feeding device 11 to place the chip on the first carrier mechanism 151 which is transferred to the feeding station.
After the feeding is finished, the first transfer device 15 transfers the chip flow to the direction detection station; the direction detection device 12 is disposed at the direction detection station, and detects whether the mounting direction of the chip, which is flowed to the direction detection station, on the first carrier mechanism 151 is the same as a preset direction or not by the control of the control device.
After the detection of the mounting direction of the chip is completed, the first transfer device 15 transfers the chip stream to the direction adjustment station; the direction adjusting device 13 is arranged at the direction adjusting station, and the mounting direction of the chip which is transferred to the direction adjusting station and is different from the preset direction is adjusted by the control of the control device.
After the adjustment of the mounting direction of the chips is completed, the first transfer device 15 transfers the chips to the feeding station; the chip feeding device 14 is arranged at the feeding station, and the chips which are circulated to the feeding station are transferred to the chip handle assembling equipment 3 under the control of the control device.
In one embodiment, the upper end of the chip mounted on the first carrier mechanism 151 is provided with a chamfer for identifying a direction. Generally speaking, the upper end of the chip can be clamped, and the lower end of the chip should be prevented from contacting other objects, so as to avoid affecting the detection accuracy of the chip.
Referring to fig. 2 to 4, the chip has opposite front and back surfaces, and opposite left and right side surfaces, and a surface perpendicular to the upper surface of the first transfer tray 152, perpendicular to the radial direction of the first transfer tray 152, and adjacent to the center of the first transfer tray 152 is used as the front surface of the chip, and with the front surface of the chip as a reference, the left side surface of the chip is the left side surface of the chip, and the right side surface of the chip is the right side surface of the chip.
After the chip is placed on the first carrier mechanism 151, if the chamfer of the chip is located on the left side surface of the upper end of the chip, the mounting direction of the chip is different from the preset direction; if the chamfer angle of the chip is positioned on the right side surface of the upper end of the chip, the mounting direction of the chip is the same as the preset direction.
If the mounting direction of the chip is the same as the preset direction, after the first transfer device 15 transfers the chip to the direction adjusting station, the direction adjusting device 13 does not need to adjust the mounting direction of the chip, the first transfer device 15 transfers the chip to the feeding station, and the chip feeding device 14 transfers the chip to the chip handle assembling equipment 3.
Therefore, on one hand, the feeding device 11, the direction detecting device 12, the direction adjusting device 13 and the chip feeding device 14 can be arranged at intervals along the periphery of the first transfer disc 152, so that the space is fully utilized, the whole feeding equipment is compact in structure, and the chip feeding efficiency is improved; on the other hand, first transport dish 152 can accomplish processes such as feeding, direction detection, direction adjustment and the pay-off of chip in proper order at the moving in-process, and closely link up between each process, can satisfy the requirement of fast beat production, is showing the efficiency that promotes the chip material loading, and the probability that the chip was put to the contrary is lower.
In a specific embodiment, the direction detection device 12 may include a first ccd camera.
The first ccd camera can determine whether the mounting direction of the chip on the first carrier mechanism 151 is the same as the preset direction by detecting the position of the chamfer of the chip on the first carrier mechanism 151. In one embodiment, the feeding device 11 may include a chip feeding mechanism 111 and a material taking mechanism 112, the chip feeding mechanism 111 may be used for placing a chip, the material taking mechanism 112 may include a 4-axis robot, the material taking mechanism 112 is in communication with the control device, and the control device may control the material taking mechanism 112 to transfer the chip placed on the chip feeding mechanism 111 to the first carrier mechanism 151 at the feeding station.
Referring to fig. 5 to 7, the chip handle feeder apparatus 2 includes: the chip handle feeding device 21, the chip handle transferring device 22, the chip handle rotating device 23 and the chip handle identifying device 24 are respectively in communication connection with the control device.
The chip handle feeding device 21 is used for containing chip handles and feeding the chip handles out under the control of the control device, and in a specific embodiment, the chip handle feeding device 21 comprises a chip handle vibration disc and a chip handle feeding groove; the chip handle transfer device 22 is provided with a receiving station 2251 and a sending-out station 2252, and the control device controls the chip handle transfer device 22 to pick up the chip handle sent out by the chip handle feeding device 21 at the receiving station 2251 and transfer the chip handle to the sending-out station 2252; the chip handle rotating device 23 is disposed adjacent to the feeding-out station 2252 of the chip handle transferring device 22, and the control device controls the chip handle rotating device 23 to pick up a chip handle from the feeding-out station 2252 of the chip handle transferring device 22 and turn the chip handle by a preset angle; the chip handle recognition device 24 is arranged adjacent to the chip handle rotating device 23, and the control device controls the chip handle recognition device 24 to recognize the direction of the chip handle on the chip handle rotating device 23. In a specific embodiment, the chip handle recognition device 24 includes a light source and a second ccd camera.
By arranging the chip handle feeding device 21, the chip handle transferring device 22, the chip handle rotating device 23 and the chip handle recognizing device 24, the chip handles are orderly contained and automatically sent to the correct position for the use of the following process, and all the devices are compact in arrangement structure, tight in connection, orderly in operation, efficient and rapid to realize the intellectualization and standardization of a chip handle feeding program.
Referring to fig. 7, in a specific embodiment, the chip handle transferring device 22 includes a fourth guiding rail 221, a first driving mechanism 222, a first carrying mechanism 223, and a chip handle transferring mechanism 224, and the first driving mechanism 222 and the chip handle transferring mechanism 224 are respectively connected to the control device in a communication manner. The first carrier mechanism 223 is disposed on the fourth guide rail 221, the chip handle transfer mechanism 224 is disposed on the first carrier mechanism 223, the first driving mechanism 222 is connected to the first carrier mechanism 223 to drive the first carrier mechanism 223 and the chip handle transfer mechanism 224 to move on the fourth guide rail 221, and the control device controls the first carrier mechanism 223 to receive a chip handle from the receiving station 2251 of the chip handle transfer device 22 and to send out the chip handle from the chip handle transfer mechanism 224 at the sending station 2252. The chip handle transfer device 22 is used for transferring the chip handle fed from the chip handle feed chute 212 from the receiving station 2251 to the feeding station 2252, specifically: the first bearing mechanism 223 is disposed on the fourth guide rail 221, and the first driving mechanism 222 is connected to the first bearing mechanism 223 to drive the first bearing mechanism 223 to slide along the fourth guide rail 221 to a position corresponding to the receiving station 2251 for receiving a chip handle; the chip handle transfer mechanism 224 is disposed on the first carrying mechanism 223, and when the first driving mechanism 222 drives the first carrying mechanism 223 to slide along the fourth guide rail 221, the chip handle transfer mechanism 224 correspondingly moves along with the first carrying mechanism 223, the chip handle transfer mechanism 224 obtains a chip handle from the first carrying mechanism 223, and transfers the chip handle to the sending-out station 2252 as the fourth guide rail 221 slides to a position corresponding to the sending-out station 2252 on the pick-up and sending-out support 225.
In a specific embodiment, the chip handle transfer mechanism 224 includes a chip handle horizontal pushing cylinder 2241 and a pushing block 2242, the chip handle horizontal pushing cylinder 2241 is in communication connection with the control device, the chip handle horizontal pushing cylinder 2241 is disposed on the first bearing mechanism 223, the chip handle horizontal pushing cylinder 2241 is connected to the pushing block 2242 to drive the pushing block 2242 to extend and retract in the direction toward the sending-out station 2252 on the sending-out station 2252, and when the pushing block 2242 extends toward the sending-out station 2252, the pushing block 2242 sends out the chip handle on the first bearing mechanism 223. The chip handle horizontal pushing cylinder 2241 is arranged on the first bearing mechanism 223, when the chip handle transfer mechanism 224 moves along with the first bearing mechanism 223, the chip handle horizontal pushing cylinder 2241 also moves, and the chip handle horizontal pushing cylinder 2241 drives the pushing block 2242 to extend along the direction of the sending-out station 2252, so that a chip handle is sent out; when the chip handle transfer mechanism 224 finishes a chip handle sending task, the chip handle horizontal pushing cylinder 2241 drives the pushing block 2242 to contract along the sending-out station 2252 direction.
In a specific embodiment, a containing groove for containing a chip handle is provided on the first bearing mechanism 223, the pushing block 2242 has a pushing portion, the pushing portion of the pushing block 2242 is contained in the containing groove of the first bearing mechanism 223, and the pushing portion of the pushing block 2242 is used for pushing and sending out the chip handle in the containing groove of the first bearing mechanism 223. When the chip handle needs to be sent out, the first bearing mechanism 223 runs to the position where the chip handle accommodating groove on the first bearing mechanism 223 corresponds to the chip handle accommodating groove corresponding to the receiving station 2251 on the receiving and sending support 225 along the fourth guide rail 221, the first bearing mechanism 223 is stationary, and the chip handle is pushed and sent out by the pushing part of the pushing block 2242.
In a specific embodiment, the chip handle transferring device 22 further includes a receiving slot and a sending slot respectively and correspondingly disposed on the receiving station 2251 and the sending station 2252 of the receiving rack 225, the receiving slot of the receiving rack 225 is connected to the chip handle feeding device 21 to receive the chip handle b sent by the chip handle feeding device 21, the first carrying mechanism 223 receives the chip handle b from the receiving slot of the receiving rack 225, the sending slot of the receiving rack 225 is used to receive the chip handle b sent by the chip handle transferring mechanism 224, and the chip handle rotating device 23 picks up the chip handle b from the sending slot of the receiving rack 225. The number of receiving stations 2251 on the receiving bracket 225 is corresponding to the number of stations for sending out chip handles on the feeding chute; the number of the sending-out stations 2252 on the picking rack 225 corresponds to the number of the sending-out stations 2252 of the chip handles on the first carrier 223 and the station pitch; the receiving and delivering bracket 225 is used for receiving and pushing the chip handle b, and has two purposes in the same device, so that the equipment space is saved, and two functions are met. In a specific embodiment, the number of the receiving stations 2251 may be one, two, or three, the number of the sending-out stations 2252 may be two, three, or five, the sum of the distances between all the receiving stations 2251 and all the sending-out stations 2252 on the receiving and sending support 225 is smaller than the length of the fourth guide rail 221, and the number of the receiving stations 2251 and the number of the sending-out stations 2252 are increased, so that the transfer time of the chip handle b can be effectively saved, and the transfer efficiency can be improved.
In a specific embodiment, the pick up cradle 225 further includes a blocking mechanism 2253, the blocking mechanism 2253 is disposed adjacent to the receiving slot of the pick up cradle 225, the blocking mechanism 2253 is communicatively coupled to the control device, and the control device controls the blocking mechanism 2253 to block or release the transfer of the chip handle b in the receiving slot of the pick up cradle 225 to the first carrier 223. When the receiving groove of the pick-up holder 225 receives the chip handle b without a condition for transferring to the first carriage mechanism 223, the blocking structure blocks the transfer of the chip handle b in the receiving groove of the pick-up holder 225; when the chip handle b received in the receiving groove of the pick up holder 225 can be transferred to the first carrier mechanism 223, the blocking mechanism 2253 releases the transfer of the chip handle b in the receiving groove of the pick up holder 225.
In a specific embodiment, the blocking mechanism 2253 includes a blocking cylinder 2253a and an expansion link 2253b, the blocking cylinder 2253a is connected to the expansion link 2253b to control the expansion and contraction of the expansion link 2253b, a through hole is formed on a wall of the receiving slot of the pick-up support 225 to penetrate through the inside and outside, and one end of the expansion link 2253b penetrates through the through hole of the receiving slot of the pick-up support 225 to block or release the chip handle b. When the chip handle b in the receiving groove of the receiving bracket 225 is released without any condition, the blocking cylinder 2253a controls the extension rod 2253b to extend and block the chip handle b from transferring through the through hole penetrating through the inside and the outside and provided in the groove wall of the receiving groove of the receiving bracket 225; when the chip handle b in the receiving groove of the pick-up holder 225 can be released, the blocking cylinder 2253a controls the telescopic bar 2253b to be contracted, and the chip handle b is not blocked and can be transferred. Referring to fig. 8 and 9, in a specific embodiment, the chip handle rotating device 23 includes a rotating cylinder 231 and a rotating pick-up mechanism 232, the rotating cylinder 231 is connected to the control device in communication, the rotating cylinder 231 is connected to the rotating pick-up mechanism 232 and drives the rotating pick-up mechanism 232 to rotate, and the rotating pick-up mechanism 232 is used for picking up a chip handle b. One end of the chip handle b is provided with a groove, the rotary picking mechanism 232 is provided with a plug, the plug of the rotary picking mechanism 232 is used for inserting and picking the chip handle b, and the plug of the rotary picking mechanism 232 is provided with a structure matched with the groove of the chip handle b. The structure end of the plug of the rotary picking mechanism 232 and the structure end of the groove of the chip handle b have matching structures, when the rotary picking mechanism 232 is matched with the chip handle b through the matching structures, there is no relative movement between the chip handle b and the rotary picking mechanism 232, that is, the chip handle b can perform corresponding movement along with the movement of the rotary picking mechanism 232, the rotary cylinder 231 drives the rotary picking mechanism 232 to rotate, and the rotary picking mechanism 232 picks up the chip handle b and rotates the chip handle b to a required position along with the rotation of the rotary cylinder 231.
Referring to fig. 10 to 16, the chip handle assembling apparatus 3 includes: the second transfer device 31, the pre-assembly device 32, the chip handle assembly device 33, the chip handle blanking device 34, and the defect detection device 35 may further be included, and the second transfer device 31, the pre-assembly device 32, the chip handle assembly device 33, the chip handle blanking device 34, and the defect detection device 35 are respectively in communication connection with the control device.
Referring to fig. 11, the second transfer device 31 includes a second transfer tray 311 and a plurality of second carrier mechanisms 312, a loading station, a pre-loading station, an assembling station, and a discharging station are preset in sequence along the second transfer tray 311, the plurality of second carrier mechanisms 312 are arranged at intervals along the periphery of the second transfer tray 311, the second carrier mechanisms 312 are used for carrying chips, and the control device controls the second transfer tray 311 to operate so that the second carrier mechanisms 312 are reciprocally moved between the preset stations.
The control device controls the chip feeding device 14 of the chip feeding apparatus 1 to place the chip on the second carrier mechanism 312 which is transferred to the feeding station; after the loading is finished, the second transfer device 31 transfers the chip to a preassembly station, the preassembly device 32 is arranged at the preassembly station, and the chip handle is preassembled at one end of the chip transferred to the loading station by the control of the control device; after the preassembly of the chip handles is completed, the second transfer device 31 transfers the chips and the chip handles to an assembly station, the chip handle assembly device 33 is arranged at the assembly station, and the chips and the chip handles transferred to the assembly station are assembled under the control of the control device; after the equipment of completion chip and chip handle, unloading station department is circulated with chip and chip handle to second transfer device 31, chip handle unloader 34 sets up in unloading station department, through controlling means's control, will circulate the chip and the chip handle that the unloading station was located and shift to in the chip cup of the chip box of the equipment 4 of chip cup and chip box.
The second transport plate 311 can rotate, the plurality of second carrier mechanisms 312 are arranged along the periphery of the second transport plate 311 at intervals, the second transport plate can reciprocate among preset stations, and the feeding, the transportation, the pre-installation of the chip handles, the assembly of the chips and the chip handles and the blanking are completed through the close matching of the second transport device 31, the chip feeding device 14, the pre-installation device 32, the chip handle assembly device 33 and the chip handle blanking device 34.
Referring to fig. 12, in one embodiment, the second carrier mechanism 312 includes: a fixed block 3123, a driving block 3124, a returning member (not shown), a first clamping member 3121, and a second clamping member 3122. In this embodiment, the fixing block 3123 is provided with a pair of driving blocks 3124, a pair of first clamping members 3121, and a pair of second clamping members 3122, which are respectively used for carrying two chips.
Referring to fig. 13, the fixing block 3123 is disposed at a periphery of the second transfer plate 311, a first accommodating portion 3123a is disposed on a top surface of the fixing block 3123, a second accommodating portion 3123b is disposed on a side surface of the fixing block 3123, and the first accommodating portion 3123a and the second accommodating portion 3123b of the fixing block 3123 are communicated.
The driving block 3124 includes a first end and a second end opposite to each other, the first end of the driving block 3124 is received in the second receiving portion 3123b of the fixing block 3123, the second end of the driving block 3124 is located outside the fixing block 3123, the reset member is disposed in the second receiving portion 3123b of the fixing block 3123, the reset member is, for example, a spring, two ends of the spring may respectively abut against the bottom of the second receiving portion 3123b and the first end of the driving block 3124, and when the driving block 3124 moves into the second receiving portion 3123b of the fixing block 3123, the reset member generates a force to reset the driving block 3124, so that the driving block 3124 has a tendency to move out of the fixing block 3123.
The lower end of the first clamping member 3121 and the lower end of the second clamping member 3122 are respectively disposed in the first receiving portion 3123a of the fixed block 3123, the driving block 3124 drives the first clamping member 3121 and the second clamping member 3122 to be separated when the driving block 3124 moves toward the second receiving portion 3123b of the fixed block 3123, and the driving block 3124 drives the first clamping member 3121 and the second clamping member 3122 to approach and clamp a chip between the first clamping member 3121 and the second clamping member 3122 when the driving block 3124 moves away from the second receiving portion 3123b of the fixed block 3123.
The second transfer device 31 further includes a driving mechanism, the driving mechanism is connected to the control device in a communication manner, and the control device controls the driving mechanism to drive the driving block 3124 to move into the second accommodating portion 3123b of the fixed block 3123.
When the driving mechanism drives the driving block 3124 to move toward the second receiving portion 3123b of the fixed block 3123, the first clamping member 3121 and the second clamping member 3122, which are respectively received in the first receiving portion 3123a and the second receiving portion 3123b of the fixed block 3123, are separated, and at this time, a chip may be placed between the first clamping member 3121 and the second clamping member 3122, or a chip sandwiched between the first clamping member 3121 and the second clamping member 3122 may be released; when the reset piece drives the driving block 3124 to reset, the first clamping member 3121 and the second clamping member 3122 are close, and at this time, a chip can be clamped between the first clamping member 3121 and the second clamping member 3122.
In an embodiment, the driving block 3124 is provided with a first receiving portion 3124a and a second receiving portion 3124b on a top surface thereof. The first clamping member 3121 includes a first clamping block 3121a and a first guide shaft 3121b, an upper end of the first guide shaft 3121b is connected to a lower end of the first clamping block 3121a, and a lower end of the first guide shaft 3121b is received in the first receiving portion 3124a of the driving block 3124; the second clamping member 3122 includes a second clamping block 3122a and a second guide shaft 3122b, an upper end of the second guide shaft 3122b is connected to a lower end of the second clamping block 3122a, and a lower end of the second guide shaft 3122b is received in the second receiving portion 3124b of the driving block 3124.
The upper end of the first guide shaft 3121b is connected to the first clamping block 3121a, and the lower end is received in the first receiving portion 3124a of the driving block 3124, so that when the driving block 3124 drives the first guide shaft 3121b to move inside the first receiving portion 3124a of the driving block 3124, the first clamping block 3121a is simultaneously driven to move; the second guide shaft 3122b has an upper end connected to the second clamping block 3122a and a lower end received in the second receiving portion 3124b of the driving block 3124, so that the driving block 3124 drives the second guide shaft 3122b to move inside the second receiving portion 3124b of the driving block 3124 and simultaneously drives the second clamping block 3122a to move.
When the driving block 3124 moves, the first guide shaft 3121b and the second guide shaft 3122b respectively received in the first receiving portion 3124a and the second receiving portion 3124b of the driving block 3124 also move, and since the first guide shaft 3121b is connected to the first clamping block 3121a to form the first clamping member 3121 and the second guide shaft 3122b is connected to the second clamping block 3122a to form the second clamping member 3122, the first clamping member 3121 and the second clamping member 3122 also move accordingly, so that the first clamping member 3121 and the second clamping member 3122 approach or separate from each other, a chip can be clamped when the first clamping member 3121 and the second clamping member 3122 approach each other, and a chip can be placed in or released when the second clamping member moves away from each other.
In a specific embodiment, the first receiving portion 3124a is a bar-shaped hole or a bar-shaped groove, the second receiving portion 3124b is a bar-shaped hole or a bar-shaped groove, and the first receiving portion 3124a and the second receiving portion 3124b have a splayed structure opened toward the driving mechanism. When the driving block 3124 moves toward the fixed block 3123, the first clamping member 3121 and the second clamping member 3122 also move simultaneously and gradually move away from each other, and a chip clamped between the first clamping member 3121 and the second clamping member 3122 is released or a chip is put in; when the driving block 3124 moves away from the fixed block 3123, the first clamping member 3121 and the second clamping member 3122 also move simultaneously and gradually approach to sandwich a chip between the first clamping member 3121 and the second clamping member 3122.
Referring to fig. 10 to 13, in an embodiment, the second accommodating portion 3123b is disposed on an outer side surface of the fixed block 3123 facing away from the center of the second transfer tray 311, the driving mechanism includes a feeding driving mechanism 313 and/or a discharging driving mechanism 342, the feeding driving mechanism 313 is disposed at a feeding station, and the driving block 3124 of the second carrier mechanism 312 flowing to the feeding station is driven to move into the second accommodating portion 3123b of the fixed block 3123; the blanking driving mechanism 342 is disposed at the blanking station, and is configured to drive the driving block 3124 of the second carrier mechanism 312, which is transferred to the blanking station, to move into the second accommodating portion 3123b of the fixing block 3123.
Referring to fig. 10 and 14, in one embodiment, the pre-assembly device 32 includes: the pre-assembly manipulator 321 and the pre-assembly mechanism 322 are respectively in communication connection with the control device; the pre-assembly mechanism 322 includes a pre-assembly support 3221, a chip handle carrying assembly 3222, a chip handle transferring assembly 3223, and a press-fitting assembly 3224, wherein the pre-assembly support 3221 is disposed at a pre-assembly station, the chip handle carrying assembly 3222 is disposed on the pre-assembly support 3221 in a lifting manner, the chip handle transferring assembly 3223 and the press-fitting assembly 3224 are disposed on the chip handle carrying assembly 3222, the control device controls the pre-assembly manipulator 321 to place a chip handle on the chip handle transferring assembly 3223, the control device controls the chip handle carrying assembly 3222 to drive the chip handle transferring assembly 3223 to move above the second carrier mechanism 312, and the control device controls the press-fitting assembly 3224 to press-fit the chip handle on the chip handle transferring assembly 3223 to one end of a chip of the second carrier mechanism 312.
The preassembly manipulator 321 places a chip handle on the chip handle transfer assembly 3223, the chip handle bearing assembly 3222 drives the chip handle transfer assembly 3223 to move to a position above the second carrier mechanism 312, so that the chip handle is opposite to a position right above a chip clamped on the second carrier mechanism 312, the press-mounting assembly 3224 moves towards a direction close to the chip handle transfer assembly 3223, and the chip handle accommodated on the chip handle transfer assembly 3223 is preassembled at one end of the chip clamped on the second carrier mechanism 312 at the preassembly station.
Therefore, when the pre-assembly manipulator 321 places a chip handle on the chip handle transfer assembly 3223, due to the positioning effect of the pre-assembly manipulator 321, the chip handle transfer assembly 3223 disposed on the chip handle carrying assembly 3222 needs to reach a preset height in the vertical direction as the chip handle carrying assembly 3222 disposed on the pre-assembly support 3221 is adjusted in the vertical position along the pre-assembly lifting rail 3225, then the chip handle carrying assembly 3222 drives the chip handle transfer assembly 3223 to move to a proper position above the second carrier mechanism 312 for carrying a chip, and further the press-fitting assembly 3224 presses the chip handle on the chip handle transfer assembly 3223 to the tail of the chip of the second carrier mechanism 312, that is, the pre-assembly support 3221, the chip handle carrying assembly 3222 and the chip handle transfer assembly 3223 are used for moving the chip handle directly above the chip, and the length extension line of the chip is higher than the proper position of the chip, the press-fitting assembly 3224 pre-installs the chip handle on the chip, so as to ensure that the quality of the installed product is excellent, the chip is not easy to break, the defect rate is low, the efficiency is high, and the probability of the chip being polluted is greatly reduced.
In a specific embodiment, the pre-assembly support 3221 is provided with a pre-assembly lifting rail 3225 and a pre-assembly lifting driving mechanism 3226, the pre-assembly lifting driving mechanism 3226 is in communication connection with the control device, the chip handle bearing assembly 3222 is arranged on the pre-assembly lifting rail 3225 of the pre-assembly support 3221, and the control device controls the pre-assembly lifting driving mechanism 3226 to drive the chip handle bearing assembly 3222 to lift.
The pre-assembly lifting driving mechanism 3226 is configured to drive the carrying mechanism to move along the pre-assembly lifting rail 3225 to change the position of the chip handle carrying assembly 3222 in the height direction. When the position of the chip handle carrying assembly 3222 needs to be adjusted upward, the pre-assembly lifting driving mechanism 3226 drives the chip handle carrying assembly 3222 to move upward along the pre-assembly lifting rail 3225; when the position of the chip handle carrying assembly 3222 needs to be adjusted downward, the pre-assembly lifting driving mechanism 3226 drives the chip handle carrying assembly 3222 to move downward along the pre-assembly lifting rail 3225.
In a specific embodiment, the chip handle carrying assembly 3222 includes a carrying bracket and a carrying plate (not shown), the carrying bracket is disposed on the pre-assembly lifting rail 3225 of the pre-assembly bracket 3221 in a liftable manner, the pre-assembly lifting rail 3225 is preferably located at a side surface of the pre-assembly bracket 3221, the carrying plate is disposed on the carrying bracket, and the chip handle transferring assembly 3223 and the press-fitting assembly 3224 are disposed on the carrying plate. Since the supporting bracket and the supporting plate are fixedly connected, the chip handle transferring assembly 3223 and the press-fitting assembly 3224 are disposed on the supporting plate, when the supporting bracket moves upward or downward along with the pre-assembly lifting rail 3225 of the pre-assembly bracket 3221, the supporting plate moves together, and thus the positions of the chip handle transferring assembly 3223 and the press-fitting assembly 3224 are adjusted accordingly.
In a specific embodiment, the chip handle transferring assembly 3223 includes a transferring driving cylinder 3223a and two adjacently disposed transferring blocks 3223b, the transferring driving cylinder 3223a is in communication connection with the control device, a chip handle accommodating portion for accommodating a chip handle is formed between the two transferring blocks 3223b after the two transferring blocks 3223b are close to each other, the chip handle is removed from the chip handle accommodating portion after the two transferring blocks 3223b are separated from each other, and the control device controls the transferring driving cylinder 3223a to drive the two transferring blocks 3223b to separate from and close to each other.
The transfer block 3223b is used for transferring the chip handle, when the chip handle needs to be transferred, the transfer driving cylinder 3223a drives the two transfer blocks 3223b to approach to accommodate the chip handle, and after the chip handle is transferred, the transfer driving cylinder 3223a drives the two transfer blocks 3223b to separate to release the chip handle.
In a specific embodiment, the chip handle transferring assembly 3223 further includes two transferring supports 3223c, the transferring supports 3223c are disposed on the chip handle carrying assembly 3222, a transferring guide track 3223d is disposed on the transferring supports 3223c, two ends of the transferring block 3223b are respectively disposed on the transferring guide tracks 3223d of the two transferring supports 3223c, and the control device controls the transferring driving cylinder 3223a to drive the two transferring blocks 3223b to move along the extending direction of the transferring guide track 3223d so as to separate or approach the two transferring blocks 3223 b. That is, the transfer driving cylinder 3223a drives the two transfer blocks 3223b to move apart or close to each other along the extending direction of the transfer rail 3223d, so as to transfer the chip handle. When the two transfer driving cylinders 3223a simultaneously drive the two transfer blocks 3223b to move along the extending direction of the transfer guide rails 3223d to separate or approach each other, the two transfer blocks 3223b move at the same speed, and the moving distances in the same time period are equal, so that the movement of the chip handle between the two transfer blocks 3223b is more stable, the chip handle does not tilt or fall when falling, and the hole on the chip handle is more easily aligned with the tail of the chip.
In a specific embodiment, the press-fitting assembly 3224 includes a press-fitting guide rail 3224a, a press-fitting driving cylinder 3224b, and a press-fitting block 3224c, the press-fitting driving cylinder 3224b is in communication connection with the control device, the press-fitting guide rail 3224a is disposed on the chip handle carrying assembly 3222, the press-fitting block 3224c is disposed on the press-fitting guide rail 3224a, the control device controls the press-fitting driving cylinder 3224b to drive the press-fitting block 3224c to move along the press-fitting guide rail 3224a to approach or move away from the chip handle transferring assembly 3223, and the press-fitting block 3224c is configured to press-fit the chip handle on the chip handle transferring assembly 3223 at one end of the chip of the second carrier mechanism 312.
When the chip handle needs to be pressed, the pressing driving cylinder 3224b drives the pressing block 3224c to move along the pressing guide rail 3224a to be close to the chip handle transfer assembly 3223, and the chip handle is pressed at one end of the chip; after the chip handle is mounted, the press-fitting driving cylinder 3224b drives the press-fitting block 3224c to move along the press-fitting guide rail 3224a away from the chip handle transfer assembly 3223.
In a specific embodiment, a press-fitting inclined surface is disposed on a bottom surface of the press-fitting block 3224c, the press-fitting inclined surface of the press-fitting block 3224c is adjacent to an end surface of the press-fitting block 3224c facing the chip handle transfer assembly 3223, and preferably, the press-fitting inclined surface of the press-fitting block 3224c and the end surface of the press-fitting block 3224c facing the chip handle transfer assembly 3223 are in smooth transition so as to prevent the upper end of the chip handle from smoothly entering below the press-fitting inclined surface. When the press-fitting driving cylinder 3224b drives the press-fitting block 3224c to approach the chip handle transfer assembly 3223, the press-fitting inclined surface of the press-fitting block 3224c contacts the top end of the chip handle on the chip handle transfer assembly 3223 and gradually presses down the chip handle.
When the press-fitting block 3224c is close to the chip handle transfer assembly 3223, the press-fitting inclined surface of the press-fitting block 3224c first contacts the top end of the chip handle, then continues to be close to the chip handle and gradually presses down the chip handle, so that the chip handle is clamped at the tail of the chip from top to bottom on one hand, and the chip is protected from being damaged or broken off from small to large press-fitting force on the other hand.
Referring to fig. 15, in a specific embodiment, the chip handle assembling device 33 includes an assembling bracket 333, an assembling cylinder 331, and an assembling block 332, where the assembling bracket 333 is disposed at an assembling station, the assembling cylinder 331 is disposed on the assembling bracket 333, the assembling cylinder 331 is communicatively connected to the control device, the assembling cylinder 331 is connected to the assembling block 332 and drives the assembling block 332 to extend and retract under the control of the control device, and the assembling block 332 extends to assemble the chip handle pre-assembled on the chip.
The assembling cylinder 331 is connected to the assembling block 332 and drives the assembling block 332 to extend and assemble the chip handle pre-assembled on the chip, and when the assembling of the chip handle is completed, the assembling driving cylinder drives the assembling block 332 to contract and return to the initial position.
Before formal assembly, preassembly is carried out, the chip handle is gradually contacted and pressed down through the press-fitting inclined plane, so that the chip and the chip handle are matched at a correct position, and then formal assembly is carried out, so that the qualification rate of the chip handle and the chip assembly is improved. Referring to fig. 10 and 16, in one specific application, the die shank blanking device 34 includes: the blanking mechanism comprises a blanking manipulator 341 and a blanking driving mechanism 342, wherein the blanking driving mechanism 342 comprises a blanking driving cylinder 3421 and a blanking push block 3422. The chips and the chip handles are transferred to a blanking station, a blanking driving cylinder 3421 drives a blanking push block 3422 to move forwards, the first clamping member 3121 and the second clamping member 3122 are separated, the blanking push block 3422 further drives the driving block 3124 to move towards the second containing part 3123b of the fixed block 3123, and when the defect detection device 35 detects that the chips and the chip handles which are transferred to the detection station have defects, the blanking manipulator 341 picks up the chips and the chip handles from the second carrier mechanism 312 and places the chips and the chip handles at a waste recovery place; when the defect detecting device 35 detects that the chip and the chip handle transferred to the detecting station are qualified, the unloading robot 341 picks up the chip and the chip handle from the second carrier mechanism 312 and transfers them into the chip cup of the chip cartridge of the assembling apparatus 4 of the chip cup and the chip cartridge. Referring to fig. 10, in a specific embodiment, the chip handle assembling apparatus further includes a defect detecting device 35, the defect detecting device 35 is in communication connection with the control device, the preset station further includes a detecting station located between the assembling station and the blanking station, after the assembling of the chip and the chip handle is completed, the second transferring device 31 transfers the chip and the chip handle to the detecting station, the defect detecting device 35 is disposed at the detecting station, and whether the chip and the chip handle transferred to the detecting station have defects or not is detected by the control of the control device. Specifically, the defect detecting device 35 may include a light source and a third ccd camera, the light source is disposed between the third ccd camera and the chip handle of the detection station, the light source irradiates the chip and the chip handle, the third ccd camera takes a picture of the chip and the chip handle, the control device analyzes the picture taken by the third ccd camera, determines whether the assembled chip and the chip handle have defects, when the defect detecting device 35 detects that the chip and the chip handle transferred to the detection station have defects, the chip and the chip handle are transferred to the unloading station, and the chip handle unloading device 34 picks up the chip and the chip handle from the second carrier mechanism 312 and places the chip and the chip handle at the waste recovery location; when the defect detecting device 35 detects that the chip and the chip handle transferred to the detecting station are qualified, the chip and the chip handle may be transferred to the unloading station, and the chip handle unloading device 34 picks up the chip and the chip handle from the second carrier mechanism 312 and transfers the chip and the chip handle to the chip cup of the chip box of the assembling apparatus 4 for the chip cup and the chip box.
Referring to fig. 17 to 25, the chip cup and chip cartridge assembling apparatus 4 includes: the chip box feeding device 41, the chip box carrying device 42, the chip cup feeding device 43 and the chip cup assembling device 44 may further include an assembling and blanking device 45.
The cartridge feeder 41 includes: the chip box feeding mechanism 411, the chip box turning mechanism 412 and the chip box transferring mechanism 413 are respectively in communication connection with the control device. The chip box feeding mechanism 411 is stored with a plurality of chip boxes for supplying the chip boxes, the chip box transferring mechanism 413 is arranged adjacent to the chip box feeding mechanism 411 and the chip box overturning mechanism 412 so as to pick up the chip boxes from the chip box feeding mechanism 411 and place the chip boxes on the chip box overturning mechanism 412 under the control of the control device, the control device controls the chip box overturning mechanism 412 to convert the placing direction of the chip boxes, and after the placing direction of the chip boxes is converted, the control device controls the chip box transferring mechanism 413 to pick up the chip boxes after the placing direction is converted from the chip box overturning mechanism 412 and place the chip boxes on the chip box carrying device 42.
The chip cup supply device 43 includes: the chip cup feeding mechanism 431 is in communication connection with the control device, and the chip cup feeding mechanism 431 is used for sending out the chip cups. The chip cup feeding mechanism 431 may include a chip cup vibration plate 4311 and a chip cup feeding groove 4312.
The chip cup assembling device 44 is in communication connection with the control device, and the chip cup assembling device 44 is arranged adjacent to the chip cup feeding device 43 and the chip box carrying device 42 to pick up the chip cups from the chip cup feeding device 43 and place the chip cups in the chip boxes of the chip box carrying device 42 under the control of the control device.
Borrow by above-mentioned structure, this equipment 4 of chip cup and chip box can accomplish the supply of chip cup, chip box and assemble automatically in one set of equipment, and its degree of automation is higher with assembling its manual handling relatively, and this equipment 4 of chip cup and chip box has improved the packaging efficiency of chip cup and chip box.
In one embodiment, the structure of the chip cup is shown in FIG. 18, and the structure of the chip box is shown in FIG. 19.
Specifically, referring to fig. 21, the chip cup feeding device 43 may be adapted to transfer and group the chip cups for the chip cup assembly device 44 to grasp. The chip cup feeding device 43 may further include a chip cup grouping mechanism 432, the chip cup grouping mechanism 432 is communicatively connected to the control device, the chip cup feeding mechanism 431 is connected to the chip cup grouping mechanism 432 to send out the chip cups to the chip cup grouping mechanism 432, and the control device controls the chip cup grouping mechanism 432 to group and arrange the chip cups. The chip cup assembling device 44 is arranged adjacent to the chip cup grouping mechanism 432 so as to pick up the grouped chip cups from the chip cup grouping mechanism 432 and place the chip cups in the chip box under the control of the control device, thereby saving the occupied space of the equipment.
In order to realize the automatic grouping of the chip cups and facilitate the chip cup assembling device 44 to pick up the chip cups according to the capacity of the chip box, the chip cup grouping mechanism 432 may include a chip cup transferring component 4321 and a chip cup grouping component 4322, the chip cup transferring component 4321 is in communication connection with the control device, the chip cup transferring component 4321 is connected to the chip cup feeding mechanism 431 and receives the chip cups sent by the chip cup feeding mechanism 431, the chip cup grouping component 4322 is provided with at least one chip cup accommodating portion, the control device controls the chip cup transferring component 4321 to transfer the chip cups to the chip cup accommodating portions of the chip cup grouping component 4322, and the control device controls the chip cup assembling device 44 to pick up the chip cups from the chip cup grouping component 4322 and place the chip cups in the chip box.
By means of the structure, the chip cup grouping mechanism 432 can select the proper number of the chip cups according to the planned accommodating number of the chip cups of the chip box to automatically group the chip cups, so that the chip cup assembling device 44 can pick up a plurality of chip cups at one time, the time for assembling the subsequent chip cups and the chip box is saved, and the assembling efficiency of the chip cups and the chip box is improved.
Referring to fig. 22, the chip cup assembling apparatus 44 includes a chip cup picking assembly 441, a chip cup transferring support 442, a chip cup translation guide 443, a chip cup translation driving assembly, a chip cup lifting guide 444, and a chip cup lifting driving assembly, the chip cup picking assembly 441, the chip cup translation driving assembly and the chip cup lifting driving assembly are respectively in communication connection with the control device, the chip cup translation guide 443 is disposed on the chip cup transfer holder 442, the chip cup elevation guide 444 is disposed on the chip cup translation guide 443, the chip cup picking assembly 441 is arranged on the chip cup lifting guide 444, the control device controls the chip cup translation driving assembly to drive the chip cup lifting guide 444 to move along the chip cup translation guide 443, the control device controls the chip cup lifting driving assembly to drive the chip cup picking assembly 441 to lift along the chip cup lifting guide rail 444.
When the chip cup is pushed to the chip cup accommodating portion, the chip cup picking assembly 441 located above the chip cup accommodating portion is driven by the chip cup lifting driving assembly to move up and down to pick up the chip cup, and the chip cup lifting driving assembly drives the chip cup lifting guide rail 444 to move along the chip cup translation guide rail 443 to a position above the chip box carrying device 42, so that the picked chip cup moves up and down by the chip cup picking assembly 441 via the chip cup lifting driving assembly to be placed in a chip box of the chip box carrying device 42, and the assembling and blanking device 45 is convenient to pick up the chip box assembled with the chip, the chip handle and the chip cup from the chip box carrying device 42 and transfer the chip box to a preset area. Therefore, by providing the chip cup assembling device 44, the automatic picking up and the automatic assembling of the chip cup into the chip cartridge are performed.
Specifically, referring to fig. 20 and 23, in this embodiment, the chip cassette feeding mechanism 411 may include a first sensing device 4113, a lifting assembly 4114 and at least one chip cassette feeding clip 4115, wherein the first sensing device 4113 and the lifting assembly 4114 are respectively in communication with the control device, a plurality of stacked chip cassettes are stored in the chip cassette feeding clip 4115, the control device controls the first sensing device 4113 to sense whether there is a chip cassette at the top end of the chip cassette feeding clip 4115, the lifting assembly 4114 is disposed below the chip cassette feeding clip 4115, and the control device controls the lifting assembly 4114 to lift the chip cassette in the chip cassette feeding clip 4115 so that the chip cassette moves to the top end of the chip cassette feeding clip 4115. Through the storage and automatic feeding functions of the chip box feeding mechanism 411, the chip box turning mechanism 412 and the chip box transferring mechanism 413 can be matched to supply the chip boxes to the chip box carrying device 42, so that the chip boxes can be automatically assembled with the chip cups transferred from the chip cup feeding device 43 through the chip cup assembling device 44. First sensing device 4113 detects whether there is a chip box in the chip box feeding clip 4115 at the current height, and if there is no chip box at the current height, the chip box tray jacking mechanism moves upward to ensure that the photoelectric switch detects a chip box. When setting up a plurality of chip box feed cartridge clips 4115, first sensing device 4113 can detect whether there is a chip box in all chip box feed cartridge clips 4115 of the current height, if chip box feed cartridge clip 4115 does not have a chip box at the current height, chip box bracket jacking mechanism can move upwards, ensuring that the photoelectric switch detects a chip box.
From this, through setting up chip box feed mechanism 411, realized chip box automated inspection function, realized the automatic effect of chip box supply.
In order to adjust the placing angle of the chip box so that the chip box transferring mechanism 413 can accurately transfer the chip box to the chip box carrying device 42, referring to fig. 24, the chip box turning mechanism 412 of the present embodiment may include a turning bracket 4121, a turning assembly 4122 and a turning driving mechanism 4123, the turning driving mechanism 4123 is communicatively connected to the control device, the turning assembly 4122 and the turning driving mechanism 4123 are disposed on the turning bracket 4121, the chip box transferring mechanism 413 picks up the chip box from the chip box feeding mechanism 411 and places the chip box on the turning assembly 4122, and the control device controls the turning driving mechanism 4123 to connect the turning assembly 4122 to drive the turning assembly 4122 and the chip box on the turning assembly 4122 to turn. When the chip box is placed on the chip box turning mechanism 412 by the chip box transferring mechanism 413, the turning component 4122 drives the chip box to turn at a certain angle, so that the chip box transferring mechanism 413 can pick up the chip box and place the chip box onto the chip box carrying device 42.
Referring to fig. 25, the chip carrier device 42 includes a chip carrier rail 421, a chip carrier driving assembly and a chip carrier assembly 422; the chip box carrying driving assembly is in communication connection with the control device; the chip box carrying rail 421 extends to the chip box transfer mechanism 413 and the chip cup assembling device 44, the chip box carrying assembly 422 is disposed on the chip box carrying rail 421, and the control device controls the chip box carrying driving assembly to drive the chip box carrying assembly 422 to move along the chip box carrying rail 421.
Referring to fig. 17, the assembling apparatus 4 for chip cups and chip boxes further includes a chip and chip handle feeding device and an assembling and discharging device 45, the chip and chip handle feeding device and the assembling and discharging device 45 are respectively in communication connection with the control device, the control device controls the chip and chip handle feeding device to place the chip with the chip handle in the chip cup in the chip box of the chip box carrying device 42, in a specific embodiment, the discharging manipulator 341 of the chip handle discharging device 34 is reused as the chip and chip handle feeding device, and the control device controls the assembling and discharging device 45 to pick up the chip box assembled with the chip, the chip handle and the chip cup from the chip box carrying device 42 and transfer the chip box to a preset area. Through setting up chip and chip handle loading attachment and equipment unloader 45, the equipment 4 of chip cup and chip box in this embodiment can combine together with other automatic equipment, can realize more automatic function of chip cup and chip box, and then has improved the packaging efficiency of chip cup and chip box. Referring to fig. 26 to 31, the labeling apparatus 5 includes a labeling and carrying device 51, a first labeling device 52 and a second labeling device 53, the labeling and carrying device 51, the first labeling device 52 and the second labeling device 53 are respectively connected to the control device in a communication manner, and the labeling apparatus 5 may further include a labeling and blanking device 54 and a labeling and blanking line 55; the control device controls the labeling and carrying device 51 to drive the chip boxes to move to the first labeling station and the second labeling station, and the labeling and carrying device 51 can also be used for moving the chip boxes to the labeling and blanking station.
Referring to fig. 27, the first labeling device 52 comprises: the label transfer device comprises a first label feeding mechanism 521, a first label transfer mechanism 522 and a first labeling mechanism 523, wherein the first label transfer mechanism 522 and the first labeling mechanism 523 are respectively in communication connection with the control device, the first label transfer mechanism 522 is arranged adjacent to the first label feeding mechanism 521 so as to pick up a first label from the first label feeding mechanism 521 under the control of the control device, the first label feeding mechanism 521 is a label printer, the first labeling mechanism 523 is arranged adjacent to the first label transfer mechanism 522 so as to pick up the first label from the first label transfer mechanism 522 under the control of the control device, and the control device controls the first labeling mechanism 523 to move the first attached label to a chip box of a first labeling station.
Referring to fig. 29, the second labeling device 53 includes: a second label feeding mechanism 531, a second label transferring mechanism 532, and a second labeling mechanism 533, the second label transferring mechanism 532 being disposed adjacent to the second label feeding mechanism 531 for picking up a second label from the second label feeding mechanism 531, the second label feeding mechanism 531 being, for example, a label printer, the second labeling mechanism 533 being disposed adjacent to the second label transferring mechanism 532 for picking up a second label from the second label transferring mechanism 532, the second labeling mechanism 533 attaching the second label to the chip box moved to the second labeling station.
Thus, the first labeling mechanism 523 moves and attaches the first label picked up by the first label relay mechanism 522 from the first label feeding mechanism 521 to the chip cartridge at the first labeling station, the second labeling mechanism 533 moves and attaches the second label picked up by the second label relay mechanism 532 from the second label feeding mechanism 531 to the chip cartridge at the second labeling station, and the labeling carrying device 51 transfers the chip cartridge from the first labeling station to the second labeling station. Paste mark equipment 5 through above-mentioned structure can paste the attached of mark station realization first label and second label respectively to the chip box at two, has the advantage that practices thrift manpower, degree of automation is high, can effectively improve the efficiency that the product pasted the mark.
Referring to fig. 28, the first labeling mechanism 523 may include: the first labeling support 5231, the first lifting cylinder 5232, the first labeling rotary cylinder 5233, the first pushing cylinder 5234 and the first labeling sucker 5235, wherein the first lifting cylinder 5232, the first labeling rotary cylinder 5233 and the first pushing cylinder 5234 are respectively in communication connection with the control device; first subsides mark support 5231 is last to be provided with first subsides mark guide rail 52311, first subsides mark revolving cylinder 5233 sets up on the first subsides mark guide rail 52311, controlling means control first lift cylinder 5232 drive first subsides mark revolving cylinder 5233 goes up and down along first subsides mark guide rail 52311, first subsides mark revolving cylinder 5233 is connected first flat push cylinder 5234 is in with the controlling means control down drive first flat push cylinder 5234 is rotatory, first flat push cylinder 5234 is connected first subsides mark sucking disc 5235 is in with the controlling means control down drive first subsides mark sucking disc 5235 is flexible, first subsides mark sucking disc 5235 is used for follow pick up first label on the first label transfer mechanism and with first label attached on the chip box 522 that moves to first subsides mark station.
Therefore, the first labeling mechanism 523 moves and attaches the first label picked up by the first label transferring mechanism 522 from the first label feeding mechanism 521 to the chip box conveyed to the first labeling station by the first labeling conveying device 51, the height of the picked up first label is adjusted by the first lifting cylinder 5232, and the picked up first label meets the requirement of the surface angle of the chip box by the first labeling rotating cylinder 5233. Specifically, referring to fig. 29 and 30, the second tag transferring mechanism 532 includes: the label transferring device comprises a fourth base 5321, a second label transferring cylinder 5322 and a second label transferring sucker 5323, wherein the second label transferring cylinder 5322 is in communication connection with the control device. The second label transfer cylinder 5322 is disposed on the fourth base 5321, the second label transfer suction cup 5323 is disposed on the second label transfer cylinder 5322, and the control device controls the second label transfer cylinder 5322 to drive the second label transfer suction cup 5323 to perform a linear motion so that the second label transfer suction cup 5323 moves to the second label feeding mechanism 531 and the second labeling mechanism 533.
Therefore, through the second label transferring cylinder 5322, the second label transferring suction cup 5323 can be automatically adjusted to a position suitable for picking up the label from the second label feeding mechanism 531 or the second label transferring suction cup 5323 can be automatically adjusted to a position suitable for picking up the label by the second labeling mechanism 533 according to the requirement by the second label transferring suction cup 532.
Referring to fig. 30, the second labeling mechanism 533 may include: the second labeling support 5331, the second labeling driver, the second lifting guide rail 5332, the second lifting driver, the second labeling rotary cylinder 5333 and the second labeling sucker 5334 are connected with the control device in a communication mode respectively.
The second labeling support 5331 is provided with a second labeling guide rail 53311, the second lifting guide rail 5332 is arranged on the second labeling guide rail 53311, the control device controls the second labeling driver to drive the second lifting guide rail 5332 to move along the second labeling guide rail 53311, the second labeling rotary cylinder 5333 is arranged on the second lifting guide rail 5332, the control device controls the second lifting driver to drive the second labeling rotary cylinder 5333 to lift along the second lifting guide rail 5332, the second labeling suction cup 5334 is arranged on the second labeling rotary cylinder 5333, and the control device controls the second labeling rotary cylinder 5333 to drive the second labeling suction cup 5334 to rotate so as to pick up a second label from the second label transfer mechanism 532 and attach the second label to a chip box moving to a second labeling station.
Through the above structure, the second labeling mechanism 533 moves and attaches the second label picked up by the second label transferring mechanism 532 from the second label feeding mechanism 531 to the chip box at the second labeling station, the second lifting driver drives the second labeling rotary cylinder 5333 to lift along the second lifting guide rail 5332 so as to reach the requirement of adjusting the height of the picked up second label, and the second labeling rotary cylinder 5333 rotates to make the picked up second label reach the requirement of attaching surface inclination angle of the chip box.
Referring to fig. 31, the labeling and conveying device 51 may include a labeling and conveying guide rail 511, a labeling and conveying driving assembly and a labeling and conveying assembly 512, wherein the labeling and conveying driving assembly is communicatively connected to the control device. The labeling and conveying guide rail 511 extends to a first labeling station and a second labeling station, the labeling and conveying assembly 512 is arranged on the labeling and conveying guide rail 511, and the control device controls the labeling and conveying driving assembly to drive the labeling and conveying assembly 512 to move along the labeling and conveying guide rail 511. Carry the mark product of pasting relatively artifical, more fast through setting up mark handling device 51. Referring to fig. 26, the labeling apparatus 5 further includes a labeling and blanking device 54 and a labeling and blanking line 55, the labeling and blanking device 54 is connected to the control device in a communication manner, and the labeling and carrying device 51 is further configured to move the chip boxes to a labeling and blanking station. The labeling and blanking device 54 and the labeling and blanking line 55 are arranged at a labeling and blanking station, and the control device controls the labeling and blanking device 54 to transfer the chip boxes which are labeled on the labeling and conveying device 51 to the labeling and blanking line 55.
While the present application is described in terms of various aspects, including exemplary embodiments, the principles of the invention should not be limited to the disclosed embodiments, but are also intended to cover various modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
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