Modularized joint and joint assembly for cooperative robot
1. A modular joint for a cooperative robot, comprising: the device comprises a shell (1), a driving component, an input shaft (2), an output shaft (3), a harmonic reducer (51) and a first output adaptor (6);
the input shaft (2) and the output shaft (3) are both rotatably supported by the shell (1);
the driving component is sleeved outside the input shaft (2) and is in driving connection with the input shaft (2) to rotate;
the output shaft (3) comprises a first end (301), a transition end (302) and a second end (303), the transition end (302) penetrates through the inner part of the input shaft (2), and the first end (301) and the second end (303) are exposed out of the input shaft (2);
the input shaft (2), the harmonic reducer (51), the second end (303) and the first output adaptor (6) are sequentially arranged in the axial direction of the shell (1);
the output end of the input shaft (2) is in transmission connection with the second end (303) through the harmonic reducer (51), so that the rotation of the input shaft (2) is transmitted to the output shaft (3);
the second end (303) is fixedly connected with a first output adaptor (6), and the first output adaptor (6) is used for being connected with another modular joint;
the second end (303) is disc-shaped and arranged in a torque sensor configuration.
2. A modular joint for a collaborative robot according to claim 1, characterized in that said second end (303) is rotatably supported by said housing (1).
3. A modular joint for a cooperative robot according to claim 1, wherein the second end (303) is provided as a sensor elastic body (30), the sensor elastic body (30) comprises a strain beam (33), an inner rim wheel (31) and an outer rim wheel (32) which are sleeved in and out, and a strain gauge (34) arranged on the strain beam (33);
the inner edge wheel (31) is fixedly connected with a flexible wheel (513) of the harmonic reducer (51);
the outer edge wheel (32) is fixedly connected with the first output adaptor (6);
the inner end of the strain beam (33) is connected with the inner edge wheel (31), and the outer end of the strain beam (33) is connected with the outer edge wheel (32);
the length direction of the strain beam (33) is arranged in the radial direction of the inner rim wheel (31).
4. A modular joint for a collaborative robot according to claim 3, characterized in that said strain beams (33) are four in number, four of said strain beams (33) being arranged in a cross around said inner rim wheel (31);
the strain beam (33) is provided with a through hole (331), and the through hole (331) penetrates through a pair of side faces, located on the axial direction of the outer edge wheel (32), of the strain beam (33);
the side surface of the strain beam (33) which is not provided with the through hole (331) is adhered with the strain sheet (34).
5. A modular joint for a collaborative robot according to claim 3, wherein the second end (303) further comprises an annular sensor base (35);
one end face of the sensor base (35) is fixedly connected with the outer edge wheel (32), and the other end face of the sensor base (35) is fixedly connected with the first output adaptor (6).
6. Modular joint for a cooperative robot, according to claim 5, characterized in that the outer part of the sensor base (35) is rotatably supported by the housing (1) by means of bearings.
7. A modular joint for a collaborative robot according to claim 1, characterized in that the output shaft (3) comprises a through hole, and the output shaft (3) is provided with the through hole penetrating the axial direction of the output shaft (3) such that the output shaft (3) forms a hollow structure.
8. Modular joint for a collaborative robot according to claim 1, characterized in that said drive assembly comprises a hollow motor comprising a motor stator (41) fixedly connected to said housing (1), a motor rotor (42) connected to said input shaft (2) and sleeved outside said input shaft (2).
9. Modular joint for a cooperative robot according to claim 1, characterized in that said harmonic reducer (51) comprises a wave generator (511), a rigid wheel (512) and a flexible wheel (513);
the wave generator (511) is connected with the output end of the input shaft (2), the rigid wheel (512) is fixedly connected with the shell (1), and the flexible wheel (513) is fixedly connected with the second end (303).
10. A modular joint for a collaborative robot according to claim 1, further comprising a brake assembly (7), wherein the brake assembly (7) comprises an input end brake disc (71) fixed to the input shaft (2), a brake pin (73), a return spring (75), and an electromagnetic drive assembly (72);
the periphery of the brake disc (71) is provided with a plurality of brake claws (711);
the brake pin (73) is arranged in the mounting groove (11) on the shell (1);
the resetting elastic piece (75) is arranged on the mounting groove (11), and two ends of the resetting elastic piece (75) are respectively abutted against the mounting groove (11) and the brake pin (73);
the electromagnetic driving assembly (72) is arranged at the top of the brake pin (51) and used for driving the brake pin (73) to move axially when power is on so as to enable the brake pin (73) to be away from the brake jaw (711), and enabling the brake pin (73) to reset by means of the resetting elastic piece (75) to block the brake jaw (711) when power is off.
11. Modular joint for a collaborative robot according to claim 10, further comprising an incremental encoder assembly (9), said incremental encoder assembly (9) comprising a read head (92), a read head mount (91), and a code wheel (93);
the reading head (92) is connected with the shell (1) through a reading head mounting seat (91), and the coded disc (93) is fixedly connected with the brake disc (71).
12. A modular joint for a collaborative robot according to claim 1, further comprising an absolute value encoder assembly (8), the absolute value encoder assembly (8) comprising an absolute value encoder stator (81) and an absolute value encoder rotor (82);
the absolute value encoder stator (81) is connected with the shell (1), and the absolute value encoder rotor (82) is connected with the first end (301).
13. Modular joint for a collaborative robot according to claim 1, characterized in that the outer axial end face of the first output adaptor (6) is provided with a positioning pin (61).
14. Modular joint for a collaborative robot according to claim 1, characterized in that the first output adaptor (6) is ring-shaped, arranged axially outside the housing (1), and radially inside the first output adaptor (6) is provided with a male quick electrical connection (62).
15. Modular joint for a collaborative robot according to claim 1, characterized in that a stop block (63) is fixedly attached to the outside of the housing (1).
16. A modular joint assembly is characterized by comprising a joint I (601), a joint II (602) and a joint quick-connection assembly (400) for connecting the joint I (601) and the joint II (602), wherein the joint II (602) drives the joint I (601) to rotate around the axis of the joint II (602) through the joint quick-connection assembly (10);
a modular joint for a collaborative robot according to any one of claims 1-15 is provided as said joint i (601);
the axis of the joint I (601) is perpendicular to the axis of the joint II (602);
the joint quick-connection assembly (400) comprises a left joint connecting plate (402) and a right joint connecting plate (404) which are correspondingly arranged on two sides of the outer shell (1) of the joint I (601) in the radial direction respectively;
the first end of the left joint connecting plate (402) is fixedly connected with the joint I (601), and the second end of the left joint connecting plate (402) is fixedly connected with the output end of an output shaft II of the joint II (602);
the first end of the right joint connecting plate (404) is fixedly connected with the joint I (601), and the second end of the right joint connecting plate (404) is rotatably connected with the joint II (602).
17. A modular joint assembly according to claim 16, wherein a second output adaptor (506) arranged coaxially with the first output adaptor (6) of the joint i (601) is fixedly connected to the joint ii (602) in the circumferential direction;
the first output adapter (6) and the second output adapter (506) are used for power supply and signal transmission between the two joint components.
18. A modular joint assembly according to claim 16, characterized in that the joint quick-connect assembly (400) further comprises a first quick-connect male plate (403), a first quick-connect female plate (401), a second quick-connect female plate (405) and a second quick-connect male plate (406);
the first end of the left joint connecting plate (402) is fixedly connected with the first quick-connection male plate (403), and the corresponding position in the shell (1) is fixedly connected with the first quick-connection female plate (401);
the shell (1) is provided with a through hole for the female end of the spring connector on the first quick-connection mother board (401) to contact with the male end of the spring connector on the first quick-connection male board (403);
the second end of the left joint connecting plate (402) is fixedly connected with the second quick-connection male plate (406), the joint II (602) is provided with the second quick-connection mother plate (405) fixedly connected with the output shaft II, and the left joint connecting plate (402) is fixedly connected with the second quick-connection mother plate (405);
the female end of the spring connector on the second quick-connection mother board (405) is in contact with the male end of the spring connector on the second quick-connection male board (406), and the second quick-connection male board (406) is electrically connected with the first quick-connection male board (403).
19. A modular joint assembly according to claim 17, wherein the output end of the output shaft ii is fixedly connected with a second fast-connection motherboard fixing seat (408), and the second fast-connection motherboard (405) is fixed inside the second fast-connection motherboard fixing seat (408);
and an open slot matched with the external profile of the second fast-connection motherboard fixing seat (408) is formed in the second end of the left joint connecting plate (402) and used for buckling the left joint connecting plate (402) outside the second fast-connection motherboard fixing seat (408).
Background
The cooperative robot can work together with people closely as high-end intelligent equipment, does not need to traditional industrial robot's protection isolation, effectively improves manufacturing enterprise's production level.
The core component of the cooperative robot is the joint structure, and the performance of the joint structure determines whether the whole cooperative robot has flexibility, safety, diversity and the capability of adapting to various complex working environments. At present, the joints of the cooperative robot are designed in a modular concept, so that the interchangeability of the joints is improved, and the joints are freely combined into a multi-degree-of-freedom mechanical arm to meet the working requirements of different conditions.
The modular joint of the cooperative robot is described in Chinese invention patent of 'a modular joint of a cooperative robot with a compact structure' with application date of 03.12.2019, application number of CN201911222729.2, and the main transmission mode of the modular joint of the cooperative robot is that a motor shaft is connected with a motor rotor and the input end of a harmonic reducer, the output end of the harmonic reducer is fixedly connected with the input end of an output flange, and the output flange completely wraps the output end of the reducer to achieve the effect of closing the reducer; the braking mode adopts a magnetic adsorption friction type, the friction plate is locked by the brake through the spring during power failure, the rotation of the motor shaft is further limited by the brake, the friction plate is sucked away by the built-in electromagnet of the brake during power-on, the spring is pressed, and the motor shaft freely rotates.
The design method causes the output flange to have overlarge volume, increases the processing difficulty and improves the processing precision. Meanwhile, due to lack of relevant designs such as force feedback and the like, the real-time stress condition of the cooperative robot cannot be detected, and the control difficulty and potential safety hazard of the robot are increased.
In view of the defects of the design scheme, a joint with reasonable structural design, reduced processing difficulty and cost and improved safety and reliability is needed.
Disclosure of Invention
The invention aims to solve the problems and provides a modular joint for a cooperative robot, which is compact in structure, safe and reliable. The invention adopts the following specific technical scheme:
a modular joint for a cooperative robot, comprising: the device comprises a shell, a driving assembly, an input shaft, an output shaft for outputting torque, a harmonic reducer and a first output adaptor;
the input shaft and the output shaft are both rotatably supported by the housing;
the driving component is sleeved outside the input shaft and is in driving connection with the input shaft to rotate;
the output shaft comprises a first end, a transition end and a second end, the transition end penetrates through the inner part of the input shaft, and the first end and the second end are exposed out of the input shaft;
the input shaft, the harmonic reducer, the second end and the first output adapter are sequentially arranged in the axial direction of the shell;
the output end of the input shaft is in transmission connection with the second end through the harmonic reducer, so that the rotation of the input shaft is transmitted to the output shaft;
the second end is fixedly connected with a first output adapter piece for being connected with another modular joint;
the second end is disc-shaped and configured as a torque sensor structure.
The invention can obtain the following technical effects:
1. by adopting the modularized and integrated design concept, the joint has the advantages of simple structure, low processing difficulty, high part interchangeability, compact structure and good expansibility so as to meet the requirements of various working environments;
2. the invention adopts the integrated design of the torque sensor and the output shaft, and the second end of the output shaft is directly arranged into a torque sensor structure, so that the real-time bearing torque of the joint is obtained, the integral safety and reliability of the joint are improved, and the axial size and the integral weight of the joint are reduced.
3. The motor set, the input shaft and the output shaft are all in a hollow structure form, so that internal wiring is facilitated, the rotating range of the joint is expanded, and the internal structure is simple and clear; the shell is made of lightweight hard aluminum alloy materials, so that the weight is light, and the load specific gravity ratio is large.
Drawings
FIG. 1 is a schematic view of a strain beam of a modular joint according to an embodiment of the present invention;
FIG. 2 is a schematic plan view of a modular joint according to an embodiment of the present invention;
FIG. 3 is a schematic structural view of an output shaft of an embodiment of the present invention;
FIG. 4 is a schematic structural view of an output shaft with a sensor base according to an embodiment of the present invention;
FIG. 5 is an exploded view of the brake assembly of an embodiment of the present invention;
FIG. 6 is a schematic view of an assembled structure of a brake assembly according to an embodiment of the present invention;
FIG. 7 is a block diagram of an incremental encoding component according to an embodiment of the present invention;
FIG. 8 is a schematic structural view of a quick connect joint assembly of an embodiment of the present invention;
FIG. 9 is a schematic structural diagram of a stop block of the apparatus of the embodiment of the present invention;
FIG. 10 is a schematic structural view of an input shaft of an embodiment of the present invention;
FIG. 11 is a schematic structural view of a joint assembly according to an embodiment of the present invention;
FIG. 12 is a schematic view of another angular configuration of a joint assembly according to an embodiment of the present invention;
FIG. 13 is a schematic structural view of a left articulating plate of an embodiment of the invention;
fig. 14 is a structural view of the joint assembly of the embodiment of the present invention with the left joint connecting plate not installed.
Wherein the reference numerals include: the structure comprises a shell 1, a mounting groove 11, a positioning hole 12, a fork roller bearing 105, a lower flange ring 109, a lower deep groove ball bearing 110, a deep groove ball bearing 112, an upper flange ring 113, a bearing end cover 114, a joint upper shell 171, a harmonic base 172, a joint lower shell 173, an input shaft 2, a first shoulder 201, a second shoulder 202, a third shoulder 203, a fourth shoulder 204, an output shaft 3, a first end 301, a transition end 302, a second end 303, a sensor elastomer 30, an inner edge wheel 31, an outer edge wheel 32, a strain beam 33, a through hole 331, a strain gauge 34, a sensor base 35, a driving circuit board 4, a circuit motherboard 40, a motor stator 41, a motor rotor 42, a harmonic reducer 51, a wave generator 511, a rigid wheel 512, a flexible wheel 513, a harmonic pressing ring 514, a first output adapter 6, a positioning pin 61, a quick electric connection male head 62, a limiting block 63, a brake assembly 7, a brake disc 71, a brake pawl 711, an electromagnetic drive assembly 72, a magnetic drive assembly, The device comprises a brake pin 73, a support pillar 74, a reset elastic piece 75, an absolute value coding assembly 8, an absolute value coder stator 81, an absolute value coder rotor 82, an absolute value coder rotor mounting seat 83, an absolute value coder stator mounting seat 84, an incremental coding assembly 9, a reading head mounting seat 91, a reading head 92, a coded disc 93, a coded disc pressing ring 94, a joint quick-connection assembly 400, a first quick-connection mother board 401, a left joint connecting board 402, a first quick-connection male board 403, a right joint connecting board 404, a second quick-connection mother board 405, a second quick-connection male board 406, a first quick-connection mother board fixing seat 407, a second quick-connection mother board fixing seat 408, a connecting positioning pin 4021, a joint I601 and a joint II 602.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not to be construed as limiting the invention.
Referring to fig. 1-14, wherein fig. 1 illustrates a perspective view of a modular joint of the present invention, and fig. 2 illustrates a plan view of a modular joint of the present invention. As shown in fig. 1-2, the joint comprises: the device comprises a shell 1, a driving component, an input shaft 2, an output shaft 3 capable of outputting torque, a harmonic reducer 51 and a first output adaptor 6; the input shaft 2 and the output shaft 3 are both rotatably supported by the shell 1; the driving component is sleeved outside the input shaft 2 and is connected with the input shaft 2 in a driving mode to rotate; the output shaft 3 includes a first end 301, a transition end 302, and a second end 303, the transition end 302 passing through the inside of the input shaft 2, the first end 301 and the second end 303 being exposed to the outside of the input shaft 2. Preferably, a small portion of the transition end 302 is exposed outside of the input shaft 2 to provide a space for mounting the harmonic reducer flexspline 513 of the harmonic reducer 51. The input shaft 2, the harmonic reducer 51, the second end 303 and the first output adaptor 6 are sequentially arranged in the axial direction of the shell 1; the output end of the input shaft 2 is in transmission connection with one end face of the second end 303 through a harmonic reducer 51, so that the rotation of the input shaft 2 is transmitted to the output shaft 3; the other end face of the second end 303 is fixedly connected with a first output adaptor 6 for connecting with another modular joint; the second end 303 is disc-shaped and is arranged in a torque sensor configuration.
The housing 1 includes, in order from top to bottom, an upper joint shell 171, a harmonic base 172, and a lower joint shell 173. The joint upper shell 171 and the harmonic base 172 are integrally formed in a cylindrical shape, and the inner diameter of the harmonic base 172 is smaller than that of the joint upper shell 171. The upper end of the harmonic base 172 is a stepped shaft-shaped positioning boss, and the positioning boss is overlapped with the end of the joint upper shell 171, so that the two are conveniently positioned in the axial direction. The upper articular shell 171 is fixedly connected with the harmonic base 172, and the harmonic base 172 is fixedly connected with the lower articular shell 173. The shell 1 is made of lightweight hard aluminum alloy materials, so that the overall weight of the joint is reduced.
Specifically, as shown in fig. 2, the modular joint includes a housing 1, and a driving assembly, an input shaft 2, a harmonic reducer 51, an output shaft 3, a first output adaptor 6, a brake assembly 7, an absolute value encoder assembly 8, and a driving circuit board 4 mounted inside the housing. The harmonic reducer 51, the driving assembly and the brake disc 71 are sequentially connected in series on the input shaft 2; the first output adaptor 6 and the absolute value encoder assembly 8 are sequentially connected in series on the output shaft 3 and are positioned at two ends.
The outer portion of the input shaft 2 is rotatably supported by the harmonic base 172 through the upper deep groove ball bearing 112 and the lower deep groove ball bearing 110. The outer part of the input shaft 2 is provided with 4 shoulders, a first shoulder 201, a second shoulder 202, a third shoulder 203 and a fourth shoulder 204, in order from the top to the bottom and from the input end to the output end. The upper deep groove ball bearing 112 is sleeved outside the input shaft 2, the upper end portion of the harmonic base 172 is fixedly connected with an upper flange ring 113, the bottom portion of a bearing inner ring of the upper deep groove ball bearing 112 is seated on the first shoulder 201, and the top portion of a bearing outer ring of the upper bearing 112 is packaged by the upper flange ring 113. The top of the bearing inner ring of the lower deep groove ball bearing 110 is abutted against the third shoulder 203, the bottom of the bearing outer ring of the lower deep groove ball bearing 110 is encapsulated by the lower flange ring 109, and the lower flange ring 109 is fixedly connected with the lower end part of the harmonic base 172. Thus, each bearing is axially positioned through the shoulder and the flange, and the installation and connection of the bearings belong to the prior art and are not described in detail herein. The structure is beneficial to the coaxial positioning of the shell 1 and the input shaft 2, and the compactness and the load-weight ratio of the joint structure can be effectively improved.
As shown in fig. 3, the output shaft 3 is designed as one piece with the torque sensor. The material is preferably integrally processed, and the material is the same. The sensor elastic body 30 is designed as a structure having a function of a torque sensor, which employs a disc type strain beam. Specifically, the second end 303 is provided as the sensor elastic body 30, and includes an inner edge wheel 31, an outer edge wheel 32, a strain beam 33, and a strain gauge 34. The top surface of the inner rim 31 is fixedly connected with the bottom surface of the flexible wheel 513. The outer rim wheel 32 is fixedly connected to the first output adaptor 6 by means of a cross roller bearing 105 mounted on the joint upper shell 171 for rotational movement. The inner race of the cross roller bearing 105 is mounted on the sensor base 35, and the outer race is fixed to the bearing cover 114 outside the housing 1 by the knuckle upper case 171. The sensor elastic body 30 is provided with four strain beams 33 uniformly arranged in a cross shape in the circumferential direction of the output shaft 3. The strain beams 33 connect the inner edge wheel 31 and the outer edge wheel 32, a through hole 331 penetrating the bottom surface is formed on the top surface of each strain beam, and the through hole 331 is preferably a kidney-shaped hole to improve the strain concentration effect. The left side and the right side are respectively stuck with a strain gauge 34 for detecting the deformation of the strain beam so as to measure the bending strain and play a role in measuring the torque borne by the joint. The integrated structure further improves the structural compactness of the joint of the cooperative robot, effectively reduces the axial size of the joint and improves the self-load weight ratio; meanwhile, the cross roller bearing 105 is adopted for supporting, so that the torque sensor can be effectively prevented from being influenced by overturning moment, the difficulty in screening detection signals of the torque sensor is greatly reduced, and the measurement precision of the sensor is improved; further, the torque sensor can feed back the load torque condition of the joint of the cooperative robot in real time, when the load is too large and other unexpected conditions occur, the load torque condition can be fed back to the driver, and the driver sends out a braking signal, so that the safety protection performance of the robot is improved.
Compared with the traditional technology, if the torque of the output shaft is measured, the torque sensor needs to be purchased, and the torque sensor is installed outside the shell by using an additional tool, so that the weight of the joint and the volume of the joint in the axial direction are increased, and time and labor are wasted. The additional tooling also reduces the accuracy of the torque sensor. In addition, because the shutdown design of the robot is varied, the sizes of the output shafts are different, the torque sensor can only correspondingly measure the size of a single output shaft, and when the sizes of the output shaft and the torque sensor are not used, an additional adapter is needed to connect the output shaft and the torque sensor.
The output shaft 3 is of a hollow structure, and is provided with an axial through hole penetrating through the output shaft 3, so that the wiring inside the joint is convenient.
In a preferred embodiment of the invention the output shaft 3 further comprises a sensor base 35. Since the peripheral wheel 32 needs to be rotatably supported by the housing 1 and is also fixedly connected to the first output adaptor 6. The end of the output shaft 3 is made into a split structure because of a large load, and the sensor base 35 is a cylindrical structure with a through hole formed inside and is fixedly connected with the outer rim 32. The cross roller bearing 105 is connected to the side surface of the sensor base 35, and the first output adaptor 6 is fixedly connected to one end surface of the sensor base 35. The inner edge wheel 31 of the sensor elastic body 30 is an input end of the second end 303, and the outer edge wheel 32 is fixedly connected with the sensor base 35. The sensor base 35 is an output of the second end 303. It is readily contemplated that the sensor base 35 may also be integral with the output shaft 3.
In a preferred embodiment of the present invention, the driving assembly is a hollow motor, and includes a motor stator 41 and a motor rotor 42, wherein the motor stator 41 is fixedly connected to the harmonic base 172 through an adhesive, and the motor rotor 42 is fixedly connected to the input shaft 2 through an adhesive. The bottom of the motor rotor 42 seats against the second shoulder 202. The two ends of the input shaft 2 are rotatably supported by the shell 1, and the middle of the input shaft 2 is driven by the hollow motor, so that the input shaft 2 is stably stressed. The hollow motor drives the input shaft 2 to rotate, and the installation of the hollow motor is prior art and will not be described in detail herein. The hollow motor can effectively reduce the weight and the overall dimension of the joint and improve the power density of the joint, and the hollow structure is convenient for wiring inside the joint, so that the wiring is attractive and simple.
In a preferred embodiment of the present invention, a harmonic reducer 51 is connected to the output end of the input shaft 2. The harmonic reducer 51 includes a wave generator 511, a rigid gear 512, a flexible gear 513, and a harmonic pressure ring 514. The wave generator 511 is fixedly connected to the input shaft 2 by bolts, and the top thereof overlaps the fourth shoulder 204 to be axially positioned. The rigid wheel 512 is fixedly connected with the harmonic base 172 through bolts, and a shoulder corresponding to the rigid wheel 512 is arranged on the inner wall surface of the harmonic base 172, so that the top of the rigid wheel 512 is abutted with the shoulder at the lower end of the harmonic base 172. This ensures the mounting accuracy of the harmonic reducer 51. The harmonic speed reducer 51 has the advantages of high speed reduction ratio, small external dimension and light weight. Wherein, the harmonic reducer flexspline 513 is disposed between the end portion of the input shaft 2 and the second end 303, and the other end of the harmonic reducer flexspline 513 is fixedly connected to the top surface of the sensor elastic body 30.
More specifically, the other end of the flexible gear 513 of the harmonic reducer is provided with a circular groove, and the circular harmonic pressing ring 514 is installed in the circular groove, and the top surface of the circular groove is abutted against the top surface of the circular groove. The corresponding position of the output shaft 3 is in a stepped shaft shape to form a shoulder, and the bottom surface of the harmonic pressing ring 514 is abutted against the shoulder of the output shaft 3; in the radial direction, the harmonic pressure ring 514 is in turn sandwiched between the output shaft 3 and the flexspline 513. The harmonic pressure ring 514 is fixedly connected with the second end 303 of the output shaft 3 and the flexible gear 513.
The hollow motor is connected with a wave generator 511 through an input shaft 2, a harmonic reducer 51 transmits power to an output shaft 3 through speed reduction movement and torque improvement, and the output shaft 3 transmits the movement to the next joint through a first output adapter 6; output shaft 3 and torque sensor design are as an organic whole, and then can measure the joint and receive the moment of torsion, give driving circuit board 4 with data transfer through the data line, and driving circuit board 4 assigns corresponding instruction control cavity motor motion after handling data, realizes articular initiative compliance control, improves the holistic safe and reliable degree of cooperation robot.
In a preferred embodiment of the present invention, the braking assembly 7 includes a brake disc 71 fixedly installed at an input end (an end away from the sensor elastic body 30) of the input shaft 2 and having a plurality of braking pawls 711 at an outer periphery thereof, a braking pin 73, a return elastic member 75, and an electromagnetic driving assembly 72. The stopper pin 73 is disposed in the mounting groove 11 provided at the end of the housing 1. The elastic restoring element 75 is disposed in the mounting groove 11 and has two ends respectively abutting against the mounting groove 11 and the brake pin 73.
The electromagnetic driving assembly 72 is disposed on top of the brake pin 73 and is used for driving the brake pin 73 to move axially when power is supplied so as to enable the brake pin 73 to be away from the brake jaw 711, and enabling the brake pin 73 to reset by means of the resetting elastic member 75 so as to block the brake jaw 711 when power is lost.
The brake disc 71 is connected with the tail end of the input shaft 2, the electromagnetic driving assembly 72 is connected with the end face of the harmonic base 172 through the supporting column 74, and the brake pin 73 and the return elastic element 75 are installed in the corresponding groove 11 of the harmonic base 172. As shown in fig. 5-6, the brake disc 71 is fixedly connected with the input shaft 2 through a bolt, the electromagnetic driving assembly 72 is fixedly connected with the harmonic base 172 through two supporting columns 74, the brake pin 73 and the return elastic element 75 are sequentially installed in the groove 11, and the height of the electromagnetic driving assembly 72 can be adjusted by means of a gasket to ensure the position of the brake pin 73. The brake assembly 7 adopts a power-off brake type, and when the brake assembly works normally, the electromagnetic drive assembly 72 drives the brake pin 73 to move downwards to compress the reset elastic piece 75, so that the brake pin 73 and the brake disc 71 do not interfere with each other; when the electromagnetic driving assembly 72 receives a control signal and is powered off, the reset elastic member 75 restores to the original state, pushes the brake pin 73 to move upwards, and the brake pin 73 interferes with the brake disc 71 to limit the rotation of the input shaft 2, so that the joint braking effect is achieved.
The braking mode of prior art adopts the magnetic adsorption friction formula, and the stopper passes through the spring locking friction disc during the outage, and then limits the motor shaft through the stopper and rotates, and the built-in electro-magnet of stopper inhales away the friction disc and pushes down the spring during power-on, and the motor shaft free rotation. The heat generated during braking is large due to the adoption of magnetic adsorption friction braking, and after long-term work, scraps generated by friction plates easily enter core components such as a servo motor, a speed reducer and the like, so that the safety reliability and the working precision of the robot are seriously influenced. The above-mentioned friction disc braking scheme of adopting of contrast can effectively avoid the friction disc piece to the influence of core device, the heat that produces when reducing the braking.
Preferably, the elastic restoring element 75 is a spring, when the joint is in a working state, an electromagnet of the electromagnetic driving assembly 72 is electrified and attracted, an armature of the electromagnet overcomes the spring force to press the brake pin 73, the brake disc 71 can rotate freely, under the condition of power failure, the armature of the electromagnet is released, and under the action of the spring, the brake pin 73 bounces to block the brake disc 71 from rotating, so that the joint is limited from rotating.
The end of the housing 1 close to the brake disc 71 is provided with a groove 11 for insertion of a brake pin 73, the groove 11 preferably being a cylindrical blind hole, and correspondingly the brake pin 73 being a cylindrical pin. The elastic restoring member 75 is installed in the installation groove 21, and both ends of the elastic restoring member 75 respectively abut against the installation groove 21 and the stopper pin 73. Specifically, the elastic return element 75 is in clearance fit with the groove 11, and the elastic return element 75 is preferably a common cylindrical spring. In order to prevent the brake pin 73 from falling completely into the groove 11, the end of the brake pin 73 remote from the groove 11 is provided with a stop, which is preferably cylindrical and has an outer diameter greater than that of the brake pin 73.
An electromagnetic drive assembly 72 is provided on top of the detent pin 73 for urging the detent pin 73 towards or away from the detent pawl 711. The electromagnetic drive assembly 72 includes a drive rod, a coil, and a support base. The driving rod is specifically a cylindrical armature, and when the reset elastic element 75 is in a natural state, the driving rod abuts against the stop block, and the driving rod and the brake pin 73 are coaxially arranged.
The coil is arranged on the driving rod and used for driving the driving rod to slide along the axial direction. When the coil is electrified, the magnetic field generated by the coil attracts the driving rod to press downwards, and the driving rod pushes the brake pin 73 to overcome the elastic force of the reset elastic piece 75 to move downwards along the axial direction, so that the brake pin 73 is far away from the brake jaw 711, and the brake disc 71 synchronously rotates along with the input shaft 2; when the coil loses power, the elastic return element 75 returns to elastic deformation by virtue of elastic force, so that the elastic return element 75 pushes the brake pin 73 to move upwards, the brake pin 73 drives the driving rod to move upwards until the driving rod is reset, the brake pin 73 is abutted against the brake jaw 711, and the brake pin 73 brakes the brake disc 71 to rotate, so that the input shaft 2 is prevented from rotating. The support seat is specifically two support columns 74 which extend along the axial direction of the input shaft 2 and are arranged at one end of the shell close to the brake disc 7, and the support columns 74 penetrate through support holes arranged on the periphery of the coil.
The brake assembly 7 may further include a state detector 54 for detecting a state in which the brake pin 73 abuts against the brake dog 71. Other specific structures and control methods of the brake assembly 7 can be found in the chinese patent with application number CN201910689975.2, entitled "a cooperative robot and servo motor", and are not described herein again.
In a preferred embodiment of the present invention, the incremental encoder assembly 9 includes a reading head mounting seat 91, a reading head 92, a code wheel 93, and a code wheel pressing ring 94, wherein the reading head 92 is fixedly connected with the harmonic base 172 through the reading head mounting seat 91, and the code wheel 93 is fixedly connected with the brake disc 71 through the code wheel pressing ring 94. As shown in fig. 5, the joint motion data is acquired as the brake disk 71 rotates together with the input shaft 2. .
Absolute value encoder assembly 8 includes absolute value encoder stator 81, absolute value encoder rotor 82, absolute value encoder stator mount 84, and absolute value encoder rotor mount 83. The absolute value encoder stator 81 is connected with the harmonic base 172 through the absolute value encoder stator mounting seat 84, the absolute value encoder rotor 82 is fixedly connected with the output shaft 3 through the absolute value encoder rotor mounting seat 83, and the absolute value encoder rotor 82 rotates along with the rotation of the output shaft 3. The absolute value encoder assembly 8 can measure the rotation angle of the joint output shaft 3 in real time, so that the joint motion precision is effectively increased, and the joint reliability is improved.
In a preferred embodiment of the invention, the axial end face of the first output adaptor 6, which is located outside the housing 1, is provided with a positioning pin 61 to facilitate the positioning and docking between the joints.
The first output adaptor 6 is annular, part of which is exposed outside the housing 1, and a male quick electrical connection 62 is mounted in the annulus of the first output adaptor 6. The locating pin 61 and the quick electric connection male head 62 facilitate the mutual connection between the joints, and reduce the installation difficulty.
The one end of first output adaptor shell 1 that sets up first output adaptor 6 plays the spacing effect of machinery at the radial outside fixedly connected with stopper 63 of first output adaptor 6, and relative rotation is too big when preventing joint control to become invalid, has increased articular safe and reliable degree. And a limit screw is arranged at the corresponding position of the other joint perpendicular to the joint, and when the relative rotation angle of the two joints exceeds a set angle, the limit block 63 and the limit screw interfere with each other to prevent the joints from continuously moving relatively, so that the limit effect is realized.
The joint has the advantages of force feedback, braking and quick connection functions, and has the characteristics of high-precision position control function, force feedback flexible control function, high load-to-weight ratio, compact structure and high interchangeability. The invention adopts the design concept of modularization and integration, has simple joint structure, low processing difficulty, high part interchangeability and compact structure, and has good expansibility to meet the requirements of various working environments.
The position control of joint includes absolute value encoder subassembly and incremental encoder subassembly dual control, the rotor of absolute value encoder is fixed on the output shaft, the absolute value encoder stator is fixed on the harmonic base, thereby measure the rotational position of joint output shaft, the incremental encoder code wheel passes through the brake disc to be fixed on the input shaft, the reading head is fixed on the harmonic base, thereby obtain the rotational position of joint input shaft, can effectively reduce position measurement accumulative error through two kinds of position measurement, improve the position control precision of joint.
The invention adopts the integrated design of the torque sensor and the output shaft, obtains the real-time bearing torque of the joint, improves the integral safety and reliability of the joint, and simultaneously reduces the axial size and the integral weight of the joint; the integrated structure of the output shaft and the torque sensor comprises a torque sensor elastic body and a sensor mounting base, the sensor elastic body is of a disc cross beam structure, strain gauges are pasted on each side face of each strain beam to measure bending strain, waist-shaped through holes are formed in the strain beams to improve strain concentration effect, the output shaft is integrally supported by means of cross roller bearings, axial force and radial force borne by the output shaft are effectively offset, and accuracy of signals of the torque sensor is guaranteed.
The invention adopts an electromagnetic-brake disc type power-off braking protection structure, the braking mode adopts a brake disc and a brake pin, and the brake pin realizes the up-and-down motion through an electromagnet armature and a spring; meanwhile, a mechanical limiting structure of a limiting block is arranged, so that the safety of joint operation is guaranteed.
The motor set, the input shaft and the output shaft are all in a hollow structure form, so that internal wiring is facilitated, the rotating range of the joint is expanded, and the internal structure is simple and clear.
The shell is made of lightweight hard aluminum alloy material, so that the weight is light, and the load specific gravity ratio is large.
When the device is used, the driving circuit board 4 is connected with the absolute value encoder stator mounting seat 84 through the circuit mother board 40, supplies power to the hollow motor, the absolute value encoder assembly 8 and the brake assembly 7, controls the hollow motor and the brake assembly 7, and performs signal processing on the absolute value encoder assembly 8.
The hollow motor, the torque sensor, the absolute value encoder assembly and the incremental encoder assembly are respectively connected with the driving circuit board 4, and the driving circuit board 4 is a control core of the modular joint and plays roles in program storage, real-time calculation, signal processing, drive control and the like. The driving circuit board 4 drives the hollow motor to operate, the invention adopts a design method of integrating the output shaft and the torque sensor, adopts a braking method of an electromagnetic-brake disc, and adopts a joint quick-change device, thereby reducing the axial size of the joint to the maximum extent, avoiding the impurities of the friction plate from entering the joint and realizing the quick connection between the joints.
A modular joint assembly, as shown in fig. 11-14, comprises a joint I601, a joint II 602, and a joint quick-connection assembly 400 for connecting the two joints, wherein the joint quick-connection assembly 400 is used for power supply and signal transmission between the joint I601 and the joint II 602. The modular joint for the cooperative robot is provided with a joint I601, and the axis of the joint I601 is perpendicular to the axis of a joint II 602. The joint I is vertically arranged above the joint II which is horizontally arranged, and the two joints are integrally distributed in an inverted T shape.
The joint quick-connect assembly 400 includes a left joint connecting plate 402 and a right joint connecting plate 404 respectively disposed on both radially outer sides of the housing 1 of the joint i.
The first (i.e., upper) end of the left articulation plate 402 is fixedly attached to the side of the shell of the joint i. Specifically, a first end of the left joint connecting plate 402 is fixedly connected with a first quick-connection male plate 403, and the first quick-connection male plate 403 is in a circuit board nature and is used for integrating a male end of a spring-type connector. The corresponding position fixedly connected with first fast mother board 401 in the inside of shell 1, first fast mother board 401 is the circuit board on the whole, and it is female to integrate the spring connector on it. More specifically, the first fast motherboard 401 is connected to the absolute value encoder stator mounting seat 84 through the first fast motherboard fixing seat 407. The joint lower shell 173 is provided with a positioning hole 12 which is convenient for realizing positioning with a connecting positioning pin 4021 arranged at a position corresponding to the left joint connecting plate 402, so that accurate butt joint of the male plate and the female plate is ensured. Shell 1 has seted up the through-hole, supplies female end of spring formula connector and the public end of spring connector to form primary and secondary interface, can carry out the point and touch, realizes the transmission of the first end of left joint connecting plate 402 and the signal of telecommunication of joint I.
The second end (i.e. the lower part) of the left joint connecting plate 402 is fixedly connected with the output end of the output shaft II of the joint II. A second end of the left joint connecting plate 402 is fixedly connected with a second quick-connect male plate 406, and the second quick-connect male plate 406 is of a circuit board nature and is used for integrating a male end of a spring type connector. And a second quick connection mother board 405 is fixed on the end face of an output shaft II of the joint II, and the second quick connection mother board 405 is of a circuit board nature and is used for integrating a female end of the spring type connector.
More specifically, an annular second quick-connection mother board fixing seat 408 is fixed outside the output end of the output shaft II, and is used for installing and protecting the second quick-connection mother board 405. A circular open slot is formed in the second end of the corresponding left joint connecting plate 402, so that the second end is in a circular cap shape matched with the shape of the second quick-connection motherboard fixing seat 408, and the second quick-connection male plate 406 is arranged in the circular cap. The left joint connecting plate 402 can be buckled on the second quick-connection motherboard fixing seat 408, so that the stability during connection is ensured and the positioning function is also realized. The female end of the spring connector on the second fast connecting mother board 405 contacts with the male end of the spring connector on the second fast connecting male board 406, and the second fast connecting male board 406 is electrically connected with the first fast connecting male board 403.
More specifically, the second fast mother board 405 has a mark hole, and the corresponding position of the second fast mother board fixing seat 408 is also provided with a mark hole, so that the circumferential directions of the second fast mother board 405 and the second fast mother board can have the positioning and marking functions when the second fast mother board 405 is installed, and the installation is fast.
The first (i.e., upper) end of the right articulation plate 404 is fixedly attached to the joint i. The first end of the right articulation plate 404 is disposed opposite the first end of the left articulation plate 402.
The second end of the right joint connecting plate 404 is rotatably connected with the axial end face, far away from the output shaft II, of the joint II. The shell of joint II rotates and supports and has the bearing, and the second end of right joint connecting plate 404 can overlap on the bearing, and right joint connecting plate 404 has the supporting role to the connection of two joints.
A second output adaptor 506 coaxially arranged with the first output adaptor 6 of the joint I is fixedly connected to the circumference of the joint II, and the first output adaptor 6 and the second output adaptor 506 are distributed at two ends of the same joint component. The first output adaptor 6 and the second output adaptor 506, respectively from different joint assemblies, can be interconnected, enabling modular connection of the two joint assemblies, as well as power supply and signal transmission of the two joint assemblies.
Preferably, the end face of the second output adaptor 506 is provided with a positioning hole corresponding to the positioning pin 61 of the first output adaptor 6, and the positioning hole and the positioning pin 61 are matched for use, so that the two joints can be quickly positioned. And a limiting screw matched with the limiting block 63 is also arranged on the shell of the joint II.
The joint assembly adopts the connection mode of the joint quick-connection assembly, so that the joints can be conveniently and quickly connected and replaced, and the interchangeability of the joints is improved. And the joint connects II rotations of output shaft that the setting of subassembly realizes II inside joints to drive joint I around II rotations of joint, and the joint connects the subassembly soon and can let the signal of telecommunication transmission between two joints again very simple, compares with prior art, has reduced various extra electric connecting device, convenient dismantlement, raises the efficiency.
In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.
While embodiments of the present invention have been shown and described above, it should be understood that the above embodiments are exemplary and should not be taken as limiting the invention. Variations, modifications, substitutions and alterations of the above-described embodiments may be made by those of ordinary skill in the art without departing from the scope of the present invention.
The above embodiments of the present invention should not be construed as limiting the scope of the present invention. Any other corresponding changes and modifications made according to the technical idea of the present invention should be included in the protection scope of the claims of the present invention.
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