Manufacturing process of inflation-free tire high polymer material

文档序号:504 发布日期:2021-09-17 浏览:59次 中文

1. The manufacturing process of the non-pneumatic tire polymer material is characterized by comprising a material receiving frame (1), an internal mixing operation frame (2), a material conveying circular tube (3), a stirring mixing component (4), a separating component (5), a clamping component (6), a conveying material pushing component (7), a blanking control component (8), a driving adjusting component (9), a spreading component (10) and a cooling component (11): the material receiving frame (1) is fixedly connected with an internal mixing operation frame (2), and the internal mixing operation frame (2) is used for mixing rubber materials; the left side of the material receiving frame (1) is communicated with a material conveying circular tube (3), and the material conveying circular tube (3) is used for discharging rubber materials; the stirring and mixing component (4) is arranged above the material collecting frame (1), and the stirring and mixing component (4) is used for stirring the rubber material in the internal mixing operation frame (2); the separation component (5) is arranged on the banburying operation frame (2), and the separation component (5) is positioned at the lower part of the banburying operation frame (2); the clamping component (6) is arranged on the material receiving frame (1); the conveying and pushing component (7) is arranged on the material receiving frame (1), and the conveying and pushing component (7) is positioned on the front side of the banburying operation frame (2); the blanking control part (8) is arranged on the banburying operation frame (2), and the blanking control part (8) is used for controlling the falling of raw materials; the blanking control part (8) is provided with a driving adjusting part (9); the spreading component (10), the spreading component (10) is arranged on the blanking control component (8); and the cooling part (11), the cooling part (11) is arranged on the internal mixing operation frame (2), and the cooling part (11) is used for cooling the rubber material.

2. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 1, wherein the stirring and mixing component (4) comprises a servo motor (41), a six-side shaft (42), a first rotating disc (43), a first support plate (44), a stirring and mixing disc rack (45), a first transmission connecting rod (46) and a heating strip (47), the servo motor (41) is fixedly installed on the front side of the material receiving frame (1), one end of an output shaft of the servo motor (41) is fixedly connected with the six-side shaft (42), the first rotating disc (43) is fixedly connected above the six-side shaft (42), the first support plate (44) is fixedly connected on the front side of the upper portion of the inner wall of the banburying operation frame (2), the stirring and mixing disc rack (45) is rotatably connected on the first support plate (44), the first rotating disc (43) is also fixedly connected above the stirring and mixing disc rack (45), and the first transmission connecting rod (46) is rotatably connected between the two first, heating strips (47) are fixedly connected on the inner wall of the banburying operation frame (2) in an evenly distributed manner.

3. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 2, wherein the partition part (5) comprises a bar-shaped rod (51), a partition plate (52) and a first extension spring (53), the bar-shaped rod (51) is fixedly connected to the outer wall of the right side of the internal mixing operation frame (2), the partition plate (52) is slidably connected to the bar-shaped rod (51), the partition plate (52) is slidably connected to the lower portion of the internal mixing operation frame (2), and the first extension spring (53) is connected between the partition plate (52) and the internal mixing operation frame (2).

4. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 3, wherein the clamping component (6) comprises a movable block frame (61), a second extension spring (62), a limiting strip (63) and a limiting spring (64), the movable block frame (61) is connected below the material receiving frame (1) in a sliding manner, the second extension spring (62) is connected between the movable block frame (61) and the material receiving frame (1), the limiting strip (63) is connected to the front side of the material receiving frame (1) in a sliding manner, the limiting strip (63) is in contact with the movable block frame (61), and the limiting spring (64) is connected between the limiting strip (63) and the material receiving frame (1).

5. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 4, wherein the material conveying and pushing component (7) comprises a spiral material conveying roller (71), a second rotating disc (72), a rotating shaft (73), a second transmission connecting rod (74), a first bevel gear (75), a movable connecting plate (76), a second bevel gear (77), an L-shaped rod (78), a first compression spring (79) and an inclined plane push plate (710), the rear side of the material receiving frame (1) is rotatably connected with the spiral material conveying roller (71), the right side of the spiral material conveying roller (71) is fixedly connected with the second rotating disc (72), the front side of the material receiving frame (1) is rotatably connected with the rotating shaft (73), the right side of the rotating shaft (73) is also fixedly connected with the second rotating disc (72), and the second transmission connecting rod (74) is rotatably connected between the two second rotating discs (72), rotation axis (73) left end fixedly connected with first bevel gear (75), banburying operation frame (2) front side right part sliding type is connected with L type pole (78), L type pole (78) below fixedly connected with activity links board (76), activity links board (76) is passed in six shaft (42), the activity links board (76) and goes up the rotation type and be connected with second bevel gear (77), second bevel gear (77) and six shaft (42) sliding type are connected, be connected with first compression spring (79) between L type pole (78) and banburying operation frame (2), activity links board (76) right side top fixed connection has inclined plane push pedal (710).

6. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 5, wherein the blanking control part (8) comprises a support frame (81), a blanking frame (82), a guide rail plate (83), a first movable baffle (84), a second compression spring (85), a guide rod (86), a second movable baffle (87) and a third compression spring (88), the support frame (81) is fixedly connected above the banburying operation frame (2), the blanking frame (82) is connected above the support frame (81), the guide rail plate (83) is symmetrically connected at the lower part of the front side of the blanking frame (82), the first movable baffle (84) is slidably connected on the guide rail plate (83), the first movable baffle (84) is in contact with the blanking frame (82), the second compression spring (85) is connected between the first movable baffle (84) and the guide rail plate (83), the guide rod (86) is fixedly connected at the lower part of the rear side of the blanking frame (82), a second movable baffle (87) is connected on the guide rod (86) in a sliding mode, the second movable baffle (87) is in contact with the blanking frame (82), and a third compression spring (88) is connected between the second movable baffle (87) and the guide rod (86).

7. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 6, wherein the driving and adjusting component (9) comprises a second support plate (91), an electric push rod (92), a hollow sleeve (93), an internal thread sleeve (94), an overrunning clutch (95), a push frame (96), a push bar (97), a third support plate (98) and a screw (99), the second support plate (91) is fixedly connected to the upper portion of the rear side of the blanking frame (82), the electric push rod (92) is fixedly installed below the second support plate (91), the hollow sleeve (93) is fixedly connected to one end of a telescopic shaft of the electric push rod (92), the internal thread sleeve (94) is rotatably connected to the lower portion of the hollow sleeve (93), the overrunning clutch (95) is fixedly connected to the outer portion of the internal thread sleeve (94), the push frame (96) is fixedly connected to the outer portion of the overrunning clutch (95), the push bar (97) is connected to the front side of the push frame, a third support plate (98) is fixedly welded at the rear side of the support frame (81), and a screw rod (99) is fixedly connected above the rear side of the third support plate (98).

8. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 7, wherein the expanding component (10) comprises a first downward pressing frame (101), a first downward pressing spring (102), a second downward pressing frame (103), a third downward pressing frame (104) and a second downward pressing spring (105), the left side of the supporting frame (81) is connected with the first downward pressing frame (101) in a sliding manner, the first downward pressing spring (102) is connected between the first downward pressing frame (101) and the supporting frame (81), the right side of the supporting frame (81) is connected with the second downward pressing frame (103), the first downward pressing spring (102) is also connected between the second downward pressing frame (103) and the supporting frame (81), the third downward pressing frame (104) is connected on the third support plate (98) in a sliding manner, and the second downward pressing spring (105) is connected between the third downward pressing frame (104) and the third support plate (98).

9. The manufacturing process of the non-pneumatic tire polymer material as claimed in claim 8, wherein the cooling component (11) comprises a cooling frame (111), a spiral cooling infusion tube (112), a liquid inlet tube (113) and a liquid outlet tube (114), the cooling frame (111) is fixedly connected to the outside of the banburying operation frame (2), the spiral cooling infusion tube (112) is communicated to the left side of the outer wall of the cooling frame (111), the spiral cooling infusion tube (112) is in contact with the outside of the circular delivery tube (3), the liquid inlet tube (113) is communicated to the lower portion of the rear side of the outer wall of the cooling frame (111), and the liquid outlet tube (114) is communicated to the lower portion of the rear side of the outer wall of the cooling frame (111).

10. A process for manufacturing a high polymer material of an inflation-free tire is characterized by comprising the following steps: s1, detecting whether all raw materials have abnormal phenomena or not, and controlling the indoor environment temperature to be 26 ℃; s2, heating the interior of the internal mixing operation frame (2) by a heating bar, adding small materials into the internal mixing operation frame (2) when an external temperature detection device detects that the temperature of the interior of the internal mixing operation frame (2) is 55-65 ℃, and stirring for 3 minutes by a stirring and mixing disc rack (45); s3, adding a proper amount of carbon black or white carbon black into the internal mixing operation frame (2) according to the production standard for enhancing the hardness of the high polymer material of the non-pneumatic tire, waiting for 4 minutes, adding 2/3 macro material and liquid into the internal mixing operation frame (2) after the high polymer material is fully softened, and stirring for 4 minutes by using a mixing disc rack (45); s4, adding the rest large materials into the internal mixing operation frame (2), stirring the mixing disc rack (45) for 5 minutes to fully mix the materials and mix the materials to form glue, and adding a proper amount of high styrene and benzoic acid into the internal mixing operation frame (2) by workers according to the production standard to enhance the hardness of the high polymer material of the non-pneumatic tire; s5, the staff opens the external cooling water supply equipment to make the cooling liquid in the spiral cooling infusion tube (112) flow circularly and make the cooling frame (111) filled with the cooling liquid to cool the rubber material, so that the temperature of the rubber material is controlled below 120 ℃, and the rubber discharging temperature can be changed slightly according to seasons; and S6, discharging the rubber through the circular conveying pipe (3) after the worker observes that the rubber inside the banburying operation frame (2) is formed for two minutes.

Background

With the development of modern engineering technology, high molecular materials are developing towards high performance, functionalization and biochemistry, and compared with common materials, the high molecular materials have more excellent performance, and the high molecular materials become important materials essential for national economic construction and daily life of people. The high polymer materials comprise plastics, rubber, fibers, films and the like, wherein the rubber material is a main material for manufacturing the non-pneumatic tire, the rubber material used by each rubber part in the non-pneumatic tire has specific performance, and the components of the rubber material depend on the requirements of the service performance of the tire.

Because the hardness of the non-pneumatic tire is far higher than that of a common tire, the rubber material for manufacturing the non-pneumatic tire is viscous, the problem of easy adhesion of the rubber material can occur in the rubber discharging process, the rubber is not convenient to discharge rapidly, the rubber discharging efficiency is low, the rubber material adhesion can cause the waste of the rubber material, more materials need to be added in the generating process, the heating temperature of the materials needs to be higher, and the temperature needs to be controlled to be more than 90 ℃ below 120 ℃ during rubber discharging.

Disclosure of Invention

Therefore, in order to solve the above problems, it is necessary to provide a manufacturing process of a polymer material for a non-pneumatic tire, which can effectively improve the discharge efficiency of rubber materials and sufficiently and effectively cool the rubber materials to ensure that the rubber discharge temperature is below 120 ℃ and above 90 ℃, so as to solve the problems that the rubber materials proposed in the background art are easy to adhere and the temperature is difficult to control below 120 ℃ and above 90 ℃ during rubber discharge.

The technical scheme is as follows: the utility model provides a exempt from pneumatic tire macromolecular material preparation technology, is including receiving material frame, banburying operation frame, defeated material pipe, stirring mixing element, partition part, screens part, carries to push away material part, blanking control part, drive adjustment part, struts part and cooling part: the internal mixing operation frame is fixedly connected above the material receiving frame and is used for internally mixing rubber materials; the left side of the material receiving frame is communicated with a material conveying circular pipe which is used for discharging the sizing material; the stirring and mixing component is arranged above the material receiving frame and is used for stirring the rubber material in the banburying operation frame; the separation component is arranged on the internal mixing operation frame and is positioned at the lower part of the internal mixing operation frame; the clamping component is arranged on the material receiving frame; the conveying and pushing component is arranged on the receiving frame and is positioned on the front side of the banburying operation frame; the blanking control part is arranged on the banburying operation frame and is used for controlling the falling of raw materials; the blanking control part is provided with a driving adjusting part; the spreading component is arranged on the blanking control component; and the cooling part is arranged on the internal mixing operation frame and is used for cooling the rubber material.

Furthermore, it is particularly preferred that the stirring mixing component comprises a servo motor, a six-side rod shaft, a first rotating disc, a first support plate, a stirring mixing disc frame, a first transmission connecting rod and a heating strip, the receiving frame is fixedly provided with the servo motor at the front side, the servo motor output shaft is fixedly connected with the six-side rod shaft at one end, the first rotating disc is fixedly connected above the six-side rod shaft, the first support plate is fixedly connected at the front side of the inner wall of the banburying operation frame, the stirring mixing disc frame is rotatably connected on the first support plate, the first rotating disc is fixedly connected above the stirring mixing disc frame, the first transmission connecting rod is rotatably connected between the two first rotating discs together, and the heating strip is fixedly connected on the inner wall of the banburying operation frame in an evenly distributed manner.

In addition, it is especially preferred that the partition part comprises a bar rod, a partition plate and a first extension spring, the bar rod is fixedly connected to the outer wall of the right side of the internal mixing operation frame, the partition plate is connected to the bar rod in a sliding mode, the partition plate is connected to the lower portion of the internal mixing operation frame in a sliding mode, and the first extension spring is connected between the partition plate and the internal mixing operation frame.

In addition, it is especially preferred that the screens part is including movable block frame, second extension spring, spacing and spacing spring, receives material frame below slidingtype and is connected with movable block frame, is connected with second extension spring between movable block frame and the receipts material frame, receives material frame front side sliding type and is connected with spacing, spacing and the contact of movable block frame, spacing and receive and be connected with spacing spring between the material frame.

In addition, particularly preferably, the conveying and pushing component comprises a spiral conveying roller, a second rotating disc, a rotating shaft, a second transmission connecting rod, a first bevel gear, a movable connecting plate, a second bevel gear, an L-shaped rod, a first compression spring and an inclined plane pushing plate, the spiral conveying roller is rotatably connected to the rear side of the receiving frame, the second rotating disc is fixedly connected to the right side of the spiral conveying roller, the rotating shaft is rotatably connected to the front side of the receiving frame, the second rotating disc is also fixedly connected to the right side of the rotating shaft, the second transmission connecting rod is rotatably connected between the two second rotating discs together, the first bevel gear is fixedly connected to the left end of the rotating shaft, the L-shaped rod is slidably connected to the right part of the front side of the banburying operation frame, the movable connecting plate is fixedly connected to the lower part of the L-shaped rod, the six-face rod shaft penetrates through the movable connecting plate, the second bevel gear is rotatably connected to the movable connecting plate, and the second bevel gear is slidably connected to the six-face rod shaft, a first compression spring is connected between the L-shaped rod and the banburying operation frame, and an inclined plane push plate is fixedly connected above the right side of the movable connecting plate.

In addition, it is particularly preferable that the blanking control part comprises a support frame, a blanking frame, a guide rail plate, a first movable baffle, a second compression spring, a guide rod, a second movable baffle and a third compression spring, the support frame is fixedly connected above the internal mixing operation frame, the blanking frame is connected above the support frame, the guide rail plate is symmetrically connected to the lower part of the front side of the blanking frame, the first movable baffle is connected to the guide rail plate in a sliding manner, the first movable baffle is in contact with the blanking frame, the second compression spring is connected between the first movable baffle and the guide rail plate, the guide rod is fixedly connected to the lower part of the rear side of the blanking frame, the second movable baffle is connected to the guide rod in a sliding manner, the second movable baffle is in contact with the blanking frame, and the third compression spring is connected between the second movable baffle and the guide rod.

In addition, it is particularly preferred that the driving adjustment part comprises a second support plate, an electric push rod, a hollow sleeve, an internal thread sleeve, an overrunning clutch, a pushing frame, a pushing strip, a third support plate and a screw rod, the second support plate is fixedly connected to the upper portion of the rear side of the blanking frame, the electric push rod is fixedly mounted below the second support plate, the hollow sleeve is fixedly connected to one end of an electric push rod telescopic shaft, the internal thread sleeve is rotatably connected to the lower portion of the hollow sleeve, the overrunning clutch is fixedly connected to the outer portion of the internal thread sleeve, the pushing frame is fixedly connected to the outer portion of the overrunning clutch, the pushing strip is connected to the front side of the pushing frame through an elastic hinge, the third support plate is fixedly welded to the rear side of the support frame, and.

In addition, it is particularly preferable that the expanding member includes a first depressing frame, a first depressing spring, a second depressing frame, a third depressing frame and a second depressing spring, the first depressing frame is slidably connected to the left side of the support frame, the first depressing spring is connected between the first depressing frame and the support frame, the second depressing frame is slidably connected to the right side of the support frame, the first depressing spring is similarly connected between the second depressing frame and the support frame, the third depressing frame is slidably connected to the third stay, and the second depressing spring is connected between the third depressing frame and the third stay.

In addition, it is especially preferred that the cooling part comprises a cooling frame, a spiral cooling infusion tube, a liquid inlet tube and a liquid outlet tube, the outside of the internal mixing operation frame is fixedly connected with the cooling frame, the left side of the outer wall of the cooling frame is communicated with the spiral cooling infusion tube, the spiral cooling infusion tube is in external contact with the circular conveying tube, the lower part of the rear side of the outer wall of the cooling frame is communicated with the liquid inlet tube, and the lower part of the rear side of the outer wall of the cooling frame is communicated with the.

A process for manufacturing a high polymer material of an inflation-free tire comprises the following steps: s1, detecting whether all raw materials have abnormal phenomena or not, and controlling the indoor environment temperature to be 26 ℃; s2, heating the internal part of the internal mixing operation frame by a heating bar, adding small materials into the internal mixing operation frame when an external temperature detection device detects that the internal temperature of the internal mixing operation frame is 55-65 ℃, and stirring the small materials by a mixing tray frame for 3 minutes; s3, adding a proper amount of carbon black or white carbon black into the internal mixing operation frame according to the production standard to enhance the hardness of the high polymer material of the non-pneumatic tire, waiting for 4 minutes, adding 2/3 macro-material and liquid into the internal mixing operation frame after the high polymer material is fully softened, and stirring the mixing disc frame for 4 minutes; s4, adding the rest large materials into the internal mixing operation frame, stirring the mixing disc frame for 5 minutes to ensure that the materials are fully mixed and are mixed to form glue, and adding a proper amount of high styrene and benzoic acid into the internal mixing operation frame by a worker according to the production standard to enhance the hardness of the high polymer material of the non-pneumatic tire; s5, the staff starts the external cooling water supply equipment to make the cooling liquid in the spiral cooling transfusion pipe flow circularly, and the cooling frame is filled with the cooling liquid to cool the rubber material, so that the temperature of the rubber material is controlled below 120 ℃, and the rubber discharging temperature can be changed slightly according to seasons; and S6, discharging the rubber through the circular conveying pipe after the worker observes that the rubber inside the banburying operation frame is formed for two minutes.

The beneficial effects are that:

according to the production standard, the staff only need manual control electric putter flexible, then can make this equipment drop into the required raw and other materials of banburying in grades, easy operation, and the practicality is strong.

At the in-process of exempting from pneumatic tire macromolecular material banburying, stir the rubber material that mixes the mixing plate rail in real time to the banburying operation frame to realize making its intensive mixing's purpose, be convenient for produce pneumatic tire macromolecular material, at the in-process of binder removal, the stirring effect of stirring the mixing plate rail can prevent the rubber material adhesion, and improve its exhaust efficiency.

According to production standards, during the second feeding period, a proper amount of carbon black or white carbon black can be added into the internal mixing operation frame, and during the third feeding period, a proper amount of high styrene and benzoic acid can be added into the internal mixing operation frame, so as to increase the hardness of the high polymer material of the non-pneumatic tire and enhance the performance of the non-pneumatic tire.

Before discharging the glue, the cooling liquid in the spiral cooling infusion tube circularly flows, and the cooling frame is filled with the cooling liquid, so that the glue discharging temperature is controlled below 120 ℃ and above 90 ℃, and the purpose of fully and effectively cooling the glue is realized.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is a partial perspective view of the material pushing conveying component of the present invention.

FIG. 5 is a schematic sectional perspective view of an agitating mixing member of the present invention.

Fig. 6 is a schematic sectional perspective view of the partition member of the present invention.

Fig. 7 is a partially cut-away perspective structural schematic view of the material conveying and pushing component of the invention.

Fig. 8 is a partial perspective view of the driving adjustment member of the present invention.

Fig. 9 is a partial perspective view of the present invention.

Fig. 10 is a schematic perspective view of the blanking control part of the present invention.

FIG. 11 is a schematic view of a first partially disassembled solid structure of the drive adjustment member of the present invention.

FIG. 12 is a schematic view of a second partially disassembled solid structure of the drive adjustment member of the present invention.

Fig. 13 is a schematic disassembled perspective view of the distracting component of the present invention.

Fig. 14 is a schematic perspective view of a first cooling member according to the present invention.

Fig. 15 is a schematic perspective view of a second cooling member according to the present invention.

FIG. 16 is a schematic view of the flow structure of the present invention.

In the figure: 1. the device comprises a material receiving frame, a banburying operation frame, a material conveying circular tube, a stirring mixing component, a servo motor, a 42, a six-side rod shaft, a 43, a first rotating disc, a 44, a first support plate, a 45, a stirring mixing disc frame, a 46, a first transmission connecting rod, a 47, a heating strip, a 5, a partition component, a 51, a strip-shaped rod, a 52, a partition plate, a 53, a first tension spring, a 6, a clamping component, a 61, a movable block frame, a 62, a second tension spring, a 63, a limiting strip, a 64, a limiting spring, a 7, a material conveying and pushing component, a 71, a spiral material conveying roller, a 72, a second rotating disc, a 73, a rotating shaft, a 74, a second transmission connecting rod, a 75, a first bevel gear, a 76, a movable connecting plate, a 77, a gear, a 78, an L-shaped rod, a 79, a first compression spring, a 710, an inclined plane push plate, a blanking control component, a 81, a support frame, a 82, a blanking frame, a 83, a six-side rod, Guide rail plate, 84, first movable baffle plate, 85, second compression spring, 86, guide rod, 87, second movable baffle plate, 88, third compression spring, 9, driving adjusting part, 91, second support plate, 92, electric push rod, 93, hollow sleeve, 94, internal thread sleeve, 95, overrunning clutch, 96, pushing frame, 97, pushing strip, 98, third support plate, 99, screw rod, 10, expanding part, 101, first pushing frame, 102, first pushing spring, 103, second pushing frame, 104, third pushing frame, 105, second pushing spring, 11, cooling part, 111, cooling frame, 112, spiral cooling infusion tube, 113, liquid inlet tube, 114 and liquid outlet tube.

Detailed Description

The standard parts used in the invention can be purchased from the market, the special-shaped parts can be customized according to the description and the description of the attached drawings, and the specific connection mode of each part adopts the conventional means of mature bolts, rivets, welding, sticking and the like in the prior art, and the detailed description is not repeated.

Example 1

A process for manufacturing a non-pneumatic tire polymer material comprises a material receiving frame 1, an internal mixing operation frame 2, a material conveying circular tube 3, a stirring mixing component 4, a separating component 5, a clamping component 6, a material conveying component 7, a blanking control component 8, a driving adjusting component 9, a spreading component 10 and a cooling component 11, wherein the internal mixing operation frame 2 is fixedly connected above the material receiving frame 1, the material conveying circular tube 3 for discharging rubber materials is communicated at the left side of the material receiving frame 1, the stirring mixing component 4 for fully stirring the rubber materials is arranged above the material receiving frame 1, the separating component 5 is arranged on the internal mixing operation frame 2, the clamping component 6 is arranged on the material receiving frame 1, the material conveying component 7 is arranged on the material receiving frame 1, the control component 8 for controlling the falling of raw materials is arranged on the internal mixing blanking frame 2, the driving adjusting component 9 is arranged on the control component 8, the spreading part 10 is arranged on the blanking control part 8, and the cooling part 11 for cooling the rubber material is arranged on the banburying operation frame 2.

As shown in fig. 5, the agitation mixing member 4 comprises a servo motor 41, a six-sided shaft 42, a first rotating disk 43, first support plate 44, stir and mix plate rail 45, first drive link 46 and heating strip 47, it has servo motor 41 to receive material frame 1 front side fixed mounting, six shaft 42 of servo motor 41 output shaft one end fixedly connected with, six shaft 42 lower parts are six rod structures, six shaft 42 top fixedly connected with first rotating disc 43, 2 inner wall upper portion front sides fixedly connected with first support plate 44 of banburying operation frame, first support plate 44 goes up the rotation type and is connected with and is used for carrying out stirring mixing plate rail 45 fully stirring to the sizing material, stir the same fixedly connected with first rotating disc 43 in mixing plate rail 45 top, common rotation type is connected with first drive link 46 between two first rotating disc 43, evenly distributed fixedly connected with heating strip 47 that is used for heating the sizing material on the banburying operation frame 2 inner wall.

As shown in fig. 6, the partition part 5 includes a bar-shaped rod 51, a partition plate 52 and a first extension spring 53, the bar-shaped rod 51 is fixedly connected to the outer wall of the right side of the internal mixing operation frame 2, the partition plate 52 is slidably connected to the bar-shaped rod 51, the partition plate 52 is located at the lower portion of the internal mixing operation frame 2, the partition plate 52 is slidably connected to the lower portion of the internal mixing operation frame 2, and the first extension spring 53 for driving the partition plate 52 to return is connected between the partition plate 52 and the internal mixing operation frame 2.

As shown in fig. 6, the clamping component 6 includes a movable block frame 61, a second extension spring 62, a limit strip 63 and a limit spring 64, the lower portion of the material receiving frame 1 is slidably connected with the movable block frame 61, the movable block frame 61 and the material receiving frame 1 are connected with the second extension spring 62 for driving the movable block frame 61 to reset, the material receiving frame 1 is connected with the limit strip 63 in a sliding manner, the limit strip 63 contacts with the movable block frame 61, and the limit strip 63 and the material receiving frame 1 are connected with the limit spring 64 for driving the limit strip 63 to move.

As shown in fig. 7, the material conveying and pushing component 7 includes a spiral delivery roller 71, a second rotating disc 72, a rotating shaft 73, a second transmission connecting rod 74, a first bevel gear 75, a movable connecting plate 76, a second bevel gear 77, an L-shaped rod 78, a first compression spring 79 and a bevel push plate 710, the rear side of the material receiving frame 1 is rotatably connected with the spiral delivery roller 71, the spiral delivery roller 71 is spiral, the right side of the spiral delivery roller 71 is fixedly connected with the second rotating disc 72, the front side of the material receiving frame 1 is rotatably connected with the rotating shaft 73, the right side of the rotating shaft 73 is also fixedly connected with the second rotating disc 72, the second rotating disc 72 is rotatably connected with the second transmission connecting rod 74, the left end of the rotating shaft 73 is fixedly connected with the first bevel gear 75, the right part of the front side of the internal mixing operation frame 2 is slidably connected with the L-shaped rod 78, the movable connecting plate 76 is fixedly connected below the L-shaped rod 78, the left side of the movable connecting plate 76 is in a circular ring structure, six link shaft 42 passes activity link 76, and the last rotation type of activity link 76 is connected with second bevel gear 77, and second bevel gear 77 is located first bevel gear 75 top, and second bevel gear 77 and six link shaft 42 sliding type are connected, are connected with between L type pole 78 and the banburying operation frame 2 and are used for driving the first compression spring 79 that L type pole 78 reset, and activity link 76 right side top fixedly connected with inclined plane push pedal 710, and inclined plane push pedal 710 lower part is the inclined plane structure.

As shown in fig. 8, 9 and 10, the blanking control part 8 includes a support frame 81, a blanking frame 82, a guide rail plate 83, a first movable baffle 84, a second compression spring 85, a guide rod 86, a second movable baffle 87 and a third compression spring 88, the support frame 81 is fixedly connected above the banburying operation frame 2, the blanking frame 82 is connected above the support frame 81, the blanking frame 82 is in a three-rectangular frame structure, the guide rail plate 83 is symmetrically connected at the lower part of the front side of the blanking frame 82, the guide rail plate 83 is slidably connected with the first movable baffle 84, the first movable baffle 84 is in a rectangular plate structure, the first movable baffle 84 is in contact with the blanking frame 82, the second compression spring 85 is connected between the first movable baffle 84 and the guide rail plate 83, the guide rod 86 is fixedly connected at the lower part of the rear side of the blanking frame 82, the second movable baffle 87 is slidably connected with the guide rod 86, the second movable baffle 87 is located between the two first movable baffles 84, the second movable baffle 87 is contacted with the blanking frame 82, and a third compression spring 88 is connected between the second movable baffle 87 and the guide rod 86.

As shown in fig. 11 and 12, the driving adjustment component 9 includes a second support plate 91, an electric push rod 92, a hollow sleeve 93, an internal thread sleeve 94, an overrunning clutch 95, a push frame 96, a push bar 97, a third support plate 98 and a screw 99, the upper portion of the rear side of the blanking frame 82 is fixedly connected with the second support plate 91, the electric push rod 92 is fixedly installed below the second support plate 91, one end of the telescopic shaft of the electric push rod 92 is fixedly connected with the hollow sleeve 93, the internal thread sleeve 94 is rotatably connected below the hollow sleeve 93, the internal thread sleeve 94 adopts a thread structure, the overrunning clutch 95 is fixedly connected outside the internal thread sleeve 94, the push frame 96 is fixedly connected outside the overrunning clutch 95, one side of the push frame 96 is annular, the push bar 97 is connected to the front side of the push frame 96 through an elastic hinge, the third support plate 98 is fixedly welded to the rear side of the support frame 81, the screw 99 is fixedly connected to, the screw 99 is externally threaded.

As shown in fig. 13, the expanding member 10 includes a first lower pressing frame 101, a first lower pressing spring 102, a second lower pressing frame 103, a third lower pressing frame 104 and a second lower pressing spring 105, the first lower pressing frame 101 is slidably connected to the left side of the supporting frame 81, the front lower portion of the first lower pressing frame 101 is in an inclined plane structure, the first lower pressing spring 102 is connected between the first lower pressing frame 101 and the supporting frame 81, the second lower pressing frame 103 is slidably connected to the right side of the supporting frame 81, the first lower pressing spring 102 is also connected between the second lower pressing frame 103 and the supporting frame 81, the third lower pressing frame 104 is slidably connected to the third support plate 98, the third lower pressing frame 104 is located below the push bar 97, and the second lower pressing spring 105 for driving the third lower pressing frame 104 to return is connected between the third lower pressing frame 104 and the third support plate 98.

As shown in fig. 14 and 15, the cooling member 11 includes a cooling frame 111, a spiral cooling infusion tube 112, a liquid inlet tube 113 and a liquid outlet tube 114, the cooling frame 111 is fixedly connected to the outside of the banburying operation frame 2, the spiral cooling infusion tube 112 for flowing the cooling liquid is connected to the left side of the outer wall of the cooling frame 111, the spiral cooling infusion tube 112 is in contact with the outside of the circular delivery tube 3, the liquid inlet tube 113 for inputting the cooling liquid into the cooling frame 111 is connected to the lower portion of the rear side of the outer wall of the cooling frame 111, and the liquid outlet tube 114 for outputting the cooling liquid is connected to the lower portion of the rear side of the outer wall of the cooling frame 111.

Firstly, all raw materials are tested and checked, all raw materials can be used only after being checked to be qualified, a feeding device is externally connected above a blanking frame 82, the temperature of the indoor environment is 26 ℃, a heating strip 47 heats the interior of an internal mixing operation frame 2, small materials are filled in the frame of the blanking frame 82 positioned on the rear side, wherein the small materials mainly comprise fillers, antioxidants, lubricants and other auxiliary agents, when an external temperature detection device detects that the temperature of the interior of the internal mixing operation frame 2 is 55-65 ℃, the small materials are required to be added into the internal mixing operation frame 2, an electric push rod 92 is manually controlled to extend and enable a hollow sleeve 93 and an upper device thereof to move downwards, a push strip 97 can push a third lower pressing frame 104 to move downwards, a second lower pressing spring 105 can be compressed accordingly, the third lower pressing frame 104 can push a second movable baffle 87 to move backwards and open the second movable baffle 87, and the third compression spring 88 can be compressed accordingly, therefore, small materials in the frame at the rear side of the blanking frame 82 fall into the internal mixing operation frame 2, when the internal thread sleeve 94 and the upper device thereof move downwards, due to the action of the screw 99, the internal thread sleeve 94 can reverse 120 degrees, the push frame 96 and the upper device thereof cannot rotate under the action of the overrunning clutch 95, then the electric push rod 92 is manually controlled to contract to enable the hollow sleeve 93 and the upper device thereof to reset upwards, due to the action of the screw 99, the internal thread sleeve 94 and the upper device thereof can rotate forwards by 120 degrees, and due to the fact that the push strip 97 is connected to the push frame 96 through the elastic hinge, the push strip 97 can move to the position above the second lower pressing frame 103.

After small materials are added, the servo motor 41 is manually controlled to be started, the servo motor 41 drives the six-side shaft 42 and the device on the six-side shaft to rotate through the output shaft, one first rotating disk 43 drives the other first rotating disk 43 and the device on the six-side shaft to rotate through the first transmission connecting rod 46, so that the stirring and mixing disk rack 45 is used for stirring for 3 minutes, and the small materials in the internal mixing operation frame 2 can be fully stirred through the stirring and mixing disk rack 45.

2/3 macro material and liquid are filled in the left side frame of the blanking frame 82, wherein the macro material comprises styrene elastomer, epoxidized rubber, nitrile rubber, heat conducting resin and polyolefin resin, the liquid component mainly comprises aromatic oil, after the stirring and mixing disc rack 45 is stirred for three minutes, a proper amount of carbon black or white carbon black is added into the internal mixing operation frame 2 according to the production standard, the weight composition range of the carbon black or white carbon black is 5-10% to increase the hardness of the sizing material in the internal mixing operation frame 2, after the mixture is sufficiently softened for 4 minutes, 2/3 macro material and liquid are required to be added into the internal mixing operation frame 2, the electric push rod 92 is manually controlled again to extend, the push rod 97 can push the second lower press frame 103 to move downwards, the first lower press spring 102 on the left side can be compressed therewith, the second lower press frame 103 can push the first movable baffle 84 on the left side to open, the second compression spring 85 on the left side is compressed, so that 2/3 large materials and liquid in the blanking frame 82 on the left side fall into the internal mixing frame 2, then the electric push rod 92 is controlled to contract manually, the second lower press frame 103 and the device thereon are reset reversely, so that the first movable baffle 84 on the left side is closed, the internal thread sleeve 94 and the device thereon rotate forward 120 degrees again, so that the push rod 97 is positioned above the first lower press frame 101, and then the stirring disc rack 45 stirs the materials in the internal mixing frame 2 for 4 minutes.

Then, the large residual materials are added into the internal mixing operation frame 2, the large residual materials are filled in the frame on the right side of the blanking frame 82, the electric push rod 92 is manually controlled to extend again, so that the push strip 97 pushes the first lower pressing frame 101 to move downwards, the first lower pressing spring 102 on the right side is compressed accordingly, the first lower pressing frame 101 pushes the first movable baffle 84 on the right side to open, the second compression spring 85 on the right side is compressed accordingly, the large residual materials in the frame on the right side of the blanking frame 82 fall into the internal mixing operation frame 2, then the electric push rod 92 is manually controlled to contract and reset, the first lower pressing frame 101 and the devices thereon are sequentially reset reversely, so that the first movable baffle 84 on the right side is closed, in the process, the push frame 96 and the devices thereon are rotated to the initial position, and then the stirring mixing disc frame 45 is used for stirring the materials in the internal mixing operation frame 2 for 5 minutes, so that the components are fully mixed and mixed into glue.

After observing that the sizing material inside the banburying operation frame 2 is formed for two minutes, the worker adds a proper amount of high styrene and benzoic acid into the banburying operation frame 2 according to the production standard, wherein the weight composition range of the high styrene and benzoic acid is 2-8%, the high styrene and benzoic acid are used for increasing the hardness of the high polymer material of the non-pneumatic tire, then the sizing material inside the banburying operation frame 2 needs to be discharged, the worker manually presses the inclined plane push plate 710 downwards, so that the inclined plane push plate 710 and the upper device thereof move downwards and push the partition plate 52 to be opened, the first compression spring 79 is compressed, the first tension spring 53 is stretched accordingly, the sizing material inside the banburying operation frame 2 falls into the material receiving frame 1, the sizing material inside the material receiving frame 1 extrudes the movable block frame 61 to move downwards, the second tension spring 62 is stretched accordingly, the movable block frame 61 does not block the limiting strip 63 any longer, the stretched limiting spring 64 is restored accordingly and drives the limiting strip 63 to move backwards, when the movable connecting plate 76 and the upper device thereof move downwards, the limiting strip 63 can clamp the movable connecting plate 76, then the worker can loosen the inclined plane push plate 710, and the movable connecting plate 76 and the upper device thereof cannot reset temporarily, so that the rubber materials in the internal mixing operation frame 2 can be discharged completely.

When the movable connecting plate 76 and the device thereon move downwards, the second bevel gear 77 contacts with the first bevel gear 75, the second bevel gear 77 drives the first bevel gear 75 and the device thereon to rotate, so that one of the second rotating disks 72 drives the other second rotating disk 72 and the device thereon to rotate through the second transmission connecting rod 74, and due to the action of the spiral conveying roller 71, the rubber material inside the material receiving frame 1 is discharged through the conveying circular pipe 3, and meanwhile, the rubber material in the internal mixing operation frame 2 is stirred by the stirring and mixing disk rack 45, so that the rubber material can fall into the material receiving frame 1 more quickly, and the adhesion of the rubber material is prevented.

The liquid inlet pipe 113 is communicated with an external cooling liquid supply end, the external temperature detection device detects the temperature of the rubber material in real time, before the rubber material is discharged, if the temperature of the rubber material exceeds 80 ℃, the external cooling liquid supply device needs to be manually controlled to supply cooling water to the inside of the cooling frame 111, meanwhile, the cooling water flows out through the liquid outlet pipe 114 and circularly flows in the spiral cooling liquid conveying pipe 112, so that the rubber material can be fully cooled, in the rubber material discharging process, the cooling liquid circularly flows in the spiral cooling liquid conveying pipe 112 all the time, the discharging temperature of the rubber material is below 120 degrees, the discharging temperature of the rubber material needs to be above 90 ℃, and when the temperature of the rubber material is controlled in a proper range, the external cooling liquid supply device is manually controlled to be closed.

After the rubber material in the material receiving frame 1 is discharged, the second extension spring 62 resets and drives the movable block frame 61 to reset, the movable block frame 61 pushes the limiting strip 63 to reset and enable the limiting strip not to block the movable connecting plate 76, the limiting spring 64 is stretched and reset, the first compression spring 79 resets and drives the L-shaped rod 78 and the device thereon to reset, the first extension spring 53 resets and drives the partition plate 52 to reset, finally, the servo motor 41 and the electric push rod 92 are manually controlled to stop operating, and the operation is repeated to continuously mix and process the inflation-free tire polymer material.

A manufacturing process of a polymer material for a non-pneumatic tire, as shown in fig. 16, comprises the following steps: s1, detecting whether all raw materials have abnormal phenomena or not, and controlling the indoor environment temperature to be 26 ℃; s2, heating the internal part of the internal mixing operation frame by a heating bar, adding small materials into the internal mixing operation frame when an external temperature detection device detects that the internal temperature of the internal mixing operation frame is 55-65 ℃, and stirring the small materials by a mixing tray frame for 3 minutes; s3, adding a proper amount of carbon black or white carbon black into the internal mixing operation frame according to the production standard to enhance the hardness of the high polymer material of the non-pneumatic tire, waiting for 4 minutes, adding 2/3 macro-material and liquid into the internal mixing operation frame after the high polymer material is fully softened, and stirring the mixing disc frame for 4 minutes; s4, adding the rest large materials into the internal mixing operation frame, stirring the mixing disc frame for 5 minutes to ensure that the materials are fully mixed and are mixed to form glue, and adding a proper amount of high styrene and benzoic acid into the internal mixing operation frame by a worker according to the production standard to enhance the hardness of the high polymer material of the non-pneumatic tire; s5, the staff starts the external cooling water supply equipment to make the cooling liquid in the spiral cooling transfusion pipe flow circularly, and the cooling frame is filled with the cooling liquid to cool the rubber material, so that the temperature of the rubber material is controlled below 120 ℃, and the rubber discharging temperature can be changed slightly according to seasons; and S6, discharging the rubber through the circular conveying pipe after the worker observes that the rubber inside the banburying operation frame is formed for two minutes.

Wherein the main materials comprise styrene elastomer, epoxy rubber, nitrile rubber, heat-conducting resin, polyolefin resin and the like; the small material comprises filler, antioxidant, lubricant, auxiliary agent, carbon black or white carbon black, high styrene, benzoic acid and the like.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

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