CN212287628U - Horizontal rubbing type high-speed parallel robot with decoupled rotation and movement freedom degrees - Google Patents
Horizontal rubbing type high-speed parallel robot with decoupled rotation and movement freedom degrees Download PDFInfo
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- CN212287628U CN212287628U CN202021540879.6U CN202021540879U CN212287628U CN 212287628 U CN212287628 U CN 212287628U CN 202021540879 U CN202021540879 U CN 202021540879U CN 212287628 U CN212287628 U CN 212287628U
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Abstract
The utility model discloses a high-speed parallel robot of formula rotation and the decoupling zero of freedom of movement is rubbed with the hands to level, a plurality of drive arrangement establish on fixed platform, and every drive arrangement includes master arm and drive unit. The movable platform is arranged below the fixed platform and comprises a connecting part which is one less than the driving arm. The rotating part is rotatably arranged in the middle of the movable platform, and the end effector is fixedly connected with the rotating part. The twisting part is arranged on the movable platform in a sliding way in the horizontal plane and can drive the rotating part to rotate. The first branch chain groups are respectively connected between the driving arms and the connecting parts in a one-to-one correspondence mode, and the second branch chain groups are connected between one of the driving arms and the twisting part. According to the utility model discloses high-speed parallel robot can realize that end effector rotates and removes the decoupling freedom, easily carries out the kinematics analysis to simplified control, orbit planning and calibration process have characteristics such as control is simple, operating efficiency height.
Description
Technical Field
The utility model belongs to the technical field of the robotechnology and specifically relates to a high-speed parallel robot of formula rotation and the decoupling zero of removal degree of freedom is rubbed with the hands to level is related to.
Background
The plastic industry, the electronic product industry, the pharmaceutical industry and the food industry make important contributions to national economy of China. Early industrial robots for the task of packaging, sorting, combining and disassembling goods of such light production lines were realized by a tandem mechanism. The series mechanism is formed by sequentially connecting all components through kinematic pairs, is of an open-loop structure, has large working space and high flexibility, but also has obvious defects: each motion joint is provided with a driving motor, so that the inertia of a motion part is large, and the dynamic performance of the robot needs to be improved; the accumulation of errors of all joints easily causes low precision of the tail end; the open loop structure causes the rigidity and the bearing capacity of the kinematic chain to be low, and the kinematic chain is easy to bend and deform.
The parallel mechanism is a closed loop structure, and a movable platform is connected with a fixed platform through at least two independent kinematic chains. Compared with a series mechanism, the parallel mechanism has the following advantages: the driving device is arranged on the fixed platform, so that the light weight of the moving part is realized, and the high-speed high-acceleration movement is easy to realize; the accumulation of joint errors is avoided, and the motion precision of the robot is improved; the movable platform is driven by a plurality of driving chains in parallel, the structure is more compact, and the movable platform has high rigidity and high bearing capacity.
Based on the advantages of the parallel mechanism, some parallel robots are widely applied in the fields of high-speed picking and the like. However, the three-degree-of-freedom Delta parallel mechanism can only realize three-dimensional high-speed translation in space and cannot realize rotation of a pickup angle; the high-speed parallel robot capable of realizing three-translation and one-rotation has the advantages of large coupling degree of general freedom degrees, high nonlinear degree of control model and complex control process.
SUMMERY OF THE UTILITY MODEL
The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a high-speed parallel robot of formula rotation and the decoupling zero of removal degree of freedom is rubbed with the hands to level, high-speed parallel robot can accomplish the three removal degree of freedom of end effector and the motion operation of a rotation degree of freedom and realize the decoupling zero of rotation and removal degree of freedom to simplified control, orbit planning and calibration process, reduce cost, and promote the operating efficiency. The high-speed parallel robot can also realize the complete rotation of the end effector, so that the parallel robot can better meet the large-swing-angle operation requirement on scattered materials in the flow line production.
According to the utility model discloses high-speed parallel robot of formula rotation and removal degree of freedom decoupling zero is rubbed with the hands to level, include: fixing a platform; the driving devices are arranged on the fixed platform, each driving device comprises an active arm and a driving unit for driving the active arm to pivot, and the driving units are arranged at intervals around the center of the fixed platform in the circumferential direction; the movable platform is arranged below the fixed platform and comprises a plurality of connecting parts, and the number of the connecting parts is one less than that of the driving arms; the rotating part is rotatably arranged in the middle of the movable platform; the end effector is fixedly connected with the rotating part; the twisting part can drive the rotating part to rotate around a vertical shaft, and the connecting parts and the twisting part are arranged at intervals around the center of the moving platform in the circumferential direction; a plurality of first branch chain groups, which are respectively connected between the plurality of driving arms and the plurality of connecting parts in a one-to-one correspondence manner; and the second branched chain group is connected between one of the driving arms and the twisting part.
According to the utility model discloses high-speed parallel robot of formula rotation and removal degree of freedom decoupling zero is rubbed with the hands to level has formed many driving chains through a plurality of drive unit, a plurality of driving arm and a plurality of first braced chain group, and many driving chains can drive a plurality of connecting portion to the realization moves platform, end effector's translation, makes end effector have three removal degree of freedom. An independent driving chain is formed by the driving unit, one driving arm and the second branched chain group, the driving chain can drive the twisting part to slide relative to the movable platform in a horizontal plane and transmit the twisting part to the rotating part, and therefore the rotating part drives the end effector to rotate around a vertical shaft, and the end effector has a rotational degree of freedom. Therefore, the connecting parts and the twisting parts are arranged at intervals around the center circumference of the movable platform, so that one degree of freedom of rotation and three degrees of freedom of movement of the end effector can be comprehensively realized, and decoupling of the degree of freedom of rotation and the degree of freedom of movement can be realized. Therefore, the non-linearity degree of the high-speed parallel robot is reduced, the processes of motion control, trajectory planning, kinematics calibration and the like are simpler, and the working efficiency of the high-speed parallel robot is improved.
In some embodiments, the first set of branches comprises: a first branched arm and a second branched arm, the first branched arm and the second branched arm being parallel to each other; the two ends of the first connecting rod are respectively connected to the upper end of the first branch chain arm and the upper end of the second branch chain arm in a matched mode through a ball socket and a ball head structure, and the first connecting rod is fixedly connected with the corresponding driving arm; two ends of the second connecting rod are respectively connected to the lower end of the first branch chain arm and the lower end of the second branch chain arm in a matched manner through a ball socket and a ball head structure, and the second connecting rod is fixedly connected with the corresponding connecting part; the first connecting piece is an elastic piece and is arranged between the first branched chain arm and the second branched chain arm in a stretching mode, and the first connecting piece comprises a plurality of first connecting pieces which are arranged along the length direction of the first branched chain arm at intervals.
In some embodiments, the second set of branches comprises: a third branched arm and a fourth branched arm, the third branched arm and the fourth branched arm being parallel to each other; the two ends of the third connecting rod are respectively connected to the upper end of the third branch chain arm and the upper end of the fourth branch chain arm in a matched manner through a ball socket and a ball head structure, and the third connecting rod is fixedly connected with the corresponding driving arm; two ends of the fourth connecting rod are respectively connected to the lower end of the third branch chain arm and the lower end of the fourth branch chain arm in a matched manner through a ball socket and a ball head structure, and the fourth connecting rod is fixedly connected with the twisting part; the second connecting piece is an elastic piece and is arranged between the third branched chain arm and the fourth branched chain arm in a stretching mode, and the second connecting piece comprises a plurality of second connecting pieces which are arranged at intervals along the length direction of the third branched chain arm.
In some optional embodiments, the first set of branches comprises: a fifth branched arm and a sixth branched arm, the fifth branched arm and the sixth branched arm being parallel to each other; the two ends of the fifth connecting rod are respectively connected to the upper end of the fifth branch chain arm and the upper end of the sixth branch chain arm through revolute pairs, and the fifth connecting rod is connected with the corresponding driving arm in a pivoting mode; the two ends of the sixth connecting rod are respectively connected to the lower end of the fifth branch chain arm and the lower end of the sixth branch chain arm through revolute pairs, and the sixth connecting rod is connected with the corresponding connecting part in a pivoting mode; and the axes of the rotation pair at the two ends of the fifth connecting rod and the axes of the rotation pair at the two ends of the sixth connecting rod are parallel to each other.
In some optional embodiments, the second set of branches comprises: a seventh branched arm and an eighth branched arm, the seventh branched arm and the eighth branched arm being parallel to each other; two ends of the seventh connecting rod are connected to the upper end of the seventh branched chain arm and the upper end of the eighth branched chain arm through revolute pairs respectively, and the seventh connecting rod is connected with the corresponding driving arm in a pivoting mode; two ends of the eighth connecting rod are respectively connected to the lower end of the seventh branch chain arm and the lower end of the eighth branch chain arm through revolute pairs, and the eighth connecting rod is connected with the twisting part in a pivoting mode; and the axes of the rotation pair at the two ends of the seventh connecting rod and the axes of the rotation pair at the two ends of the eighth connecting rod are parallel to each other.
In some optional embodiments, the second set of branches comprises: the upper end of the ninth branch link arm is connected with the corresponding driving arm through a Hooke hinge, and the lower end of the ninth branch link arm is connected with the twisting part through a Hooke hinge; the revolute pairs in the two hook joints are parallel to each other.
In some alternative embodiments, one of the two hook joints is replaced with a ball.
In some embodiments, the rotating portion is a gear, and a portion of the twisting portion engaged with the rotating portion is formed as a rack.
In some embodiments, a guide structure is arranged between the movable platform and the twisting part.
Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.
Drawings
The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
fig. 1 is a perspective view of a high-speed parallel robot according to a first embodiment of the present invention;
FIG. 2 is an enlarged view of a portion of FIG. 1 at A;
FIG. 3 is a schematic view of a portion of FIG. 1 at a different viewing angle;
fig. 4 is a perspective view of a high-speed parallel robot according to a second embodiment of the present invention;
fig. 5 is a perspective view of a high-speed parallel robot according to a third embodiment of the present invention;
fig. 6 is a perspective view of a high-speed parallel robot according to a fourth embodiment of the present invention.
Reference numerals:
a high-speed parallel robot 100;
a fixed platform 1;
a drive device 2, a master arm 21, and a drive unit 22;
the movable platform 3 and the connecting part 31;
a rotating part 4;
an end effector 5;
a twisting part 6;
a first link group 7, a first link arm 71, a second link arm 72, a first link 73, a second link 74, and a first link 75;
a second branched chain group 8, a third branched chain arm 81, a fourth branched chain arm 82, a third connecting rod 83, a fourth connecting rod 84 and a second connecting piece 85;
a guide structure 9;
a fifth branched chain arm a1, a sixth branched chain arm a2, a fifth link a3 and a sixth link a 4;
a seventh branched chain arm b1, an eighth branched chain arm b2, a seventh link b3 and an eighth link b 4;
ninth branch link arm c 1.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.
In the description of the present invention, a feature defined as "first" or "second" may explicitly or implicitly include one or more of the feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
A high-speed parallel robot 100 according to an embodiment of the present invention is described below with reference to fig. 1 to 6.
According to the embodiment of the present invention, as shown in fig. 1 and 2, the high-speed parallel robot 100 includes: the device comprises a fixed platform 1, a plurality of driving devices 2, a movable platform 3, a rotating part 4, an end effector 5, a twisting part 6, a plurality of groups of first branch chain groups 7 and second branch chain groups 8. A plurality of driving devices 2 are arranged on the fixed platform 1, each driving device 2 comprises an active arm 21 and a driving unit 22 for driving the active arm 21 to pivot, and the driving units 22 are arranged at intervals around the center of the fixed platform 1. The movable platform 3 is arranged below the fixed platform 1, and the movable platform 3 comprises a plurality of connecting parts 31, wherein the number of the connecting parts 31 is one less than that of the main driving arms 21. The rotating part 4 is rotatably arranged in the middle of the movable platform, and the end effector 5 is fixedly connected with the rotating part 4. The twisting part 6 is slidably arranged on the movable platform 3 in a horizontal plane, the twisting part 6 can drive the rotating part 4 to rotate around a vertical shaft, and the connecting parts 31 and the twisting part 6 are arranged at intervals around the center circumference of the movable platform 3. The plurality of first link groups 7 are respectively connected between the plurality of driving arms 21 and the plurality of connecting portions 31 in a one-to-one correspondence. The second branch chain group 8 is connected between one of the driving arms 21 and the twisting part 6.
It should be noted that, as used herein, the terms "upper", "lower", "horizontal" and the like are used throughout to describe relative positions of components. The upper and lower relationships defined herein with reference to the height of the ground are not defined herein, but are relative positional relationships introduced with respect to the positions of the fixed platform 1 and the movable platform 3. Therefore, a part is defined throughout, and the end close to the fixed platform 1 is the upper end, and the end far from the fixed platform 1 is the lower end, which are consistent with the description that the movable platform 3 is arranged below the fixed platform 1. Here too, it is not the horizontal and vertical relationships defined with reference to the angle of the ground, but the relative positional relationship introduced with respect to the position of the movable platform 3, which is consistent with the description that the rub portions 6 are slidably provided on the movable platform 3 in the horizontal plane.
In addition, for the convenience of describing the operation principle of the high-speed parallel robot 100 with reference to the drawings, a cartesian coordinate system composed of an X-axis, a Y-axis, and a Z-axis shown in the drawings is introduced. In a cartesian coordinate system, the Z-axis direction corresponds to the up-down direction. However, these relative indications are not intended to indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operate in a particular orientation, and are therefore not to be construed as limiting the invention.
It can be understood that the driving unit 22 can drive the driving arm 21 to pivot, the pivoted driving arm 21 drives the corresponding branched chain group to rotate and move, the driving unit 22, the driving arm 21 and the branched chain group corresponding to the driving arm 21 form a driving chain, the plurality of driving units 22, the plurality of driving arms 21 and the plurality of branched chain groups form a plurality of driving chains, and the plurality of independent driving chains can respectively control the plurality of connecting portions 31 and the twisting portions 6 on the braking platform 3.
Specifically, the plurality of first link groups 7 are connected between the plurality of driving arms 21 and the plurality of connecting portions 31 in a one-to-one correspondence. Thus, the plurality of driving units 22, the plurality of driving arms 21 and the plurality of first branch chain groups 7 form a plurality of driving chains, and the plurality of driving chains drive the plurality of connecting parts 31, thereby realizing three-dimensional translation of the movable platform 3 and the end effector 5. The plurality of driving chains form a closed loop structure for transmission, and compared with a transmission mode that the driving chains are in an open loop structure, the closed driving transmission is more stable.
The second branch chain group 8 is connected between one of the driving arms 21 and the twisting part 6. The driving unit 22, the driving arm 21 and the second branch chain group 8 form a driving chain, which can drive the twisting part 6 to slide in the horizontal plane relative to the movable platform 3, so that the twisting part 6 is transmitted to the rotating part 4, and the end effector 5 is driven by the rotating part 4 to rotate around the vertical axis. That is to say the end effector 5 has one degree of freedom of rotation about the Z-axis.
Therefore, under the matching of the driving chains, the connecting parts 31 and the twisting parts 6 are arranged at intervals around the center circumference of the movable platform 3, so that one degree of freedom of rotation and three degrees of freedom of movement of the end effector 5 can be comprehensively realized, and the decoupling of the degree of freedom of rotation and the degree of freedom of movement can be realized.
The decoupling of the rotation and movement freedom of the end effector 5 can greatly reduce the non-linear degree of the high-speed parallel robot 100, and the kinematics analysis is easy to be carried out, so that the processes of motion control, trajectory planning, kinematics calibration and the like are simpler, and the working efficiency of the high-speed parallel robot 100 is further improved. For example, when robots are used in logistics operations, it is often necessary to angle the products to suit the specific location requirements of the production line when transferring the products from storage to the production line, or from one production line to another. The utility model discloses high-speed parallel robot 100, drive unit 22, master arm 21 and second branch chain group 8 can form an independent driving chain to the drive is rubbed with the hands and is moved the platform 3 and slide relatively in the horizontal plane, and transmits to rotation portion 4, thereby end effector 5 rotates around vertical axis under the drive of rotation portion 4. Namely, the end effector 5 can realize stable rotation under the driving of one driving chain, but not rotate under the matching driving of a plurality of driving chains, thereby simplifying the process of motion control and trajectory planning, leading the transfer process of the product to become simple and efficient and greatly improving the operation efficiency.
In addition, the driving unit 22 is fixed on the stationary platform 1, not moving with the driving chain as in the conventional tandem robot. The light weight of the driving chain is favorably realized, and the dynamic response performance of the driving chain is improved. Furthermore, the drive chain is free from the load of the drive unit 22, which can reduce the energy consumption.
According to the utility model discloses high-speed parallel robot 100 has formed many driving chains through a plurality of drive unit 22, a plurality of initiative arm 21 and a plurality of first branch chain group 7, and many driving chains can drive a plurality of connecting portion 31 to the realization moves platform 3, end effector 5's translation, makes end effector 5 have three degree of freedom of movement. The driving unit 22, the driving arm 21 and the second branch chain group 8 form a driving chain, so that the twisting part 6 can be driven to slide relative to the movable platform 3 in the horizontal plane and be transmitted to the rotating part 4, and the end effector 5 is driven by the rotating part 4 to rotate around the vertical axis, so that the end effector 5 has one degree of freedom of rotation around the Z axis. Therefore, the connecting parts 31 and the twisting parts 6 are arranged at intervals around the center circumference of the movable platform 3, one rotation degree of freedom and three movement degrees of freedom of the end effector 5 can be comprehensively realized, and decoupling of the rotation degree of freedom and the movement degree of freedom can be realized. Therefore, the processes of motion control, trajectory planning, kinematics calibration and the like of the high-speed parallel robot 100 are simpler, and the working efficiency of the high-speed parallel robot 100 can be improved.
Alternatively, as shown in fig. 1, the driving device 2 may include four, the connecting portion 31 may include three, and the first tether group 7 may include three groups. Thus, the three drive units 22, the three driving arms 21 and the three first branch chain groups 7 form three drive chains. The three independent driving chains can respectively control the three connecting parts 31 correspondingly arranged, which is beneficial to improving the transmission stability of the high-speed parallel robot 100. Therefore, under the matching of the three driving chains, the translation of the movable platform 3 in three directions of an X axis, a Y axis and a Z axis can be realized, and the end effector 5 has three translation freedom degrees.
An independent driving chain formed by one driving unit 22, one driving arm 21 and the second branch chain group 8 can control the corresponding twisting part 6, so that the rotating part 4 rotates under the driving of the twisting part 6, and the end effector 5 rotates. Thus, the end effector 5 can have one degree of freedom of rotation about the Z-axis when the twisting part 6 slides in the horizontal plane relative to the movable platform 3.
Therefore, the high-speed parallel robot 100 provided by the embodiment of the present invention can realize a rotational degree of freedom and three translational degree of freedom through the driving of four driving chains, and can realize the decoupling of rotational degree of freedom and translational degree of freedom.
In other embodiments, the driving device 2 may also include three driving devices, in which case the connecting portion 31 includes two driving devices, and the first set of branches 7 includes two driving devices. The driving device 2 may also comprise five, in which case the connecting portions 31 comprise four, and the first set of branches 7 comprises four. Of course, the driving device 2 and the connecting portion 31 have more matching ways, and the specific arrangement of the driving device 2 and the connecting portion 31 is not limited herein.
In some embodiments, as shown in fig. 1 and 2, the rotating part 4 is a gear, and a portion of the twisting part 6 engaged with the rotating part 4 is formed as a rack. Thus, under the transmission of the driving unit 22, the driving arm 21 and the second branch chain group 8, the rack can slide relative to the movable platform 3 in the horizontal plane, so that the gear matched with the rack rotates, and the gear drives the end effector 5 to rotate. The gear and the rack are matched, so that the structure is simple, the transmission is stable, and the stable transmission between the driving chain and the end effector 5 is favorably realized. In addition, the matching form of the gear and the rack also has a steering effect, so that the high-speed parallel robot 100 is more compact in structure and more convenient to control. For example, the sliding direction of the gear is parallel to the upper surface of the movable platform 3, the direction of the rotating axis of the gear is vertical to the upper surface of the movable platform 3, and the horizontal sliding of the twisting part 6 relative to the movable platform 3 is converted into the rotation of the rotating part 4 and the end effector 5 around the Z axis through the matching of the gear and the rack.
In some embodiments, as shown in fig. 3, a guiding structure 9 is provided between the movable platform 3 and the twisting part 6. It can be understood that the guide structure 9 can limit and guide the sliding of the twisting part 6, thereby improving the sliding stability and precision of the twisting part 6. Alternatively, the guide structure 9 may be a guide rail or a guide groove, which can achieve the above functions, and the specific structure of the guide structure 9 is not limited herein.
The first and second branch groups are further described below in conjunction with fig. 1, 2, 4-6.
In the first embodiment, as shown in fig. 1, the structure of the first branch chain group 7 and the structure of the second branch chain group 8 are the same. Therefore, the high-speed parallel robot 100 has a simple structure, is convenient for operations such as processing and assembly, and is also convenient for controlling the movement of the branch chain set.
Specifically, as shown in fig. 1, the first branch chain group 7 includes: a first branched arm 71, a second branched arm 72, a first link 73, and a second link 74. The first and second link arms 71 and 72 are parallel to each other. This is advantageous in further improving the rigidity of each first link group 7 and in improving the transmission synchronism of the first link arm 71 and the second link arm 72.
As shown in fig. 1, both ends of the first link 73 are respectively connected between the upper end of the first branched link arm 71 and the upper end of the second branched link arm 72, and the first link 73 is fixedly connected to the corresponding active arm 21. The arrangement of the first link 73 can serve to connect the first branch link arm 71 and the second branch link arm 72, and also facilitate the driving arm 21 to be respectively transmitted to the first branch link arm 71 and the second branch link arm 72, and further improve the transmission synchronism of the first branch link arm 71 and the second branch link arm 72.
As shown in fig. 1 and 2, both ends of the second link 74 are connected between the lower end of the first link arm 71 and the lower end of the second link arm 72, and the second link 74 is fixedly connected to the corresponding connecting portion 31. The second link 74 is disposed to connect the first link arm 71 and the second link arm 72, so that the first link arm 71 and the second link arm 72 can be respectively driven to the corresponding connecting portion 31, and the driving synchronism of the first link arm 71 and the second link arm 72 can be further improved.
Further, the two ends of the first link 73 are engaged with the first and second link arms 71 and 72 through ball and socket structures. It will be appreciated that the first and second link arms 71 and 72 have a high degree of rotational freedom relative to the first link 73 by direct engagement of the ball and socket and ball structure.
The two ends of the second connecting rod 74 are matched with the first and second branch chain arms 71 and 72 through ball-and-socket and ball-head structures respectively. Whereby the first and second link arms 71 and 72 have a high degree of freedom of rotation with respect to the second link 74.
As shown in fig. 1, the first branch chain group 7 further includes: and a first link 75, the first link 75 being an elastic member and being disposed between the first link arm 71 and the second link arm 72 in tension. The first connecting element 75 can thus exert a certain pretension on the first and second link arms 71, 72, so that the operational stability of the first link set 7 is increased.
Further, as shown in fig. 1, the first link 75 includes a plurality and is disposed at intervals along the length direction of the first link arm 71. The arrangement of the plurality of first connecting pieces 75 can further increase the pretightening force between the first branch chain arm 71 and the second branch chain arm 72, thereby further improving the operation stability of the first branch chain group 7.
As shown in fig. 1, the second branch chain group 8 includes: a third branched link arm 81, a fourth branched link arm 82, a third link 83, and a fourth link 84. The third and fourth branched link arms 81 and 82 are parallel to each other. This is advantageous in further improving the rigidity of the second branch link group 8 and improving the transmission synchronization of the third branch link arm 81 and the fourth branch link arm 82.
As shown in fig. 1, both ends of the third link 83 are respectively connected between the upper end of the third branched chain arm 81 and the upper end of the fourth branched chain arm 82, and the third link 83 is fixedly connected to the corresponding active arm 21. The third link 83 is disposed to connect the third branched link arm 81 and the fourth branched link arm 82, so as to facilitate the driving arm 21 to transmit to the third branched link arm 81 and the fourth branched link arm 82, respectively, and further improve the transmission synchronism of the third branched link arm 81 and the fourth branched link arm 82.
As shown in fig. 1 and 2, both ends of the fourth link 84 are connected between the lower end of the third branched link arm 81 and the lower end of the fourth branched link arm 82, respectively, and the fourth link 84 is fixedly connected to the twisting part 6. The fourth link 84 is disposed to connect the third link arm 81 and the fourth link arm 82, so that the third link arm 81 and the fourth link arm 82 can be respectively transmitted to the twisting part 6, and the transmission synchronicity of the third link arm 81 and the fourth link arm 82 can be further improved.
Specifically, the two ends of the third link 83 are respectively engaged with the third and fourth branched link arms 81 and 82 through ball and socket and ball structures. It will be appreciated that the third and fourth arms 81 and 82 have a higher degree of rotational freedom relative to the third link 83 by direct engagement of the ball and socket and ball structure.
The two ends of the fourth connecting rod 84 are matched with the third branch chain arm 81 and the fourth branch chain arm 82 through ball-and-socket and ball-head structures respectively. The third and fourth branched link arms 81 and 82 thus have a high degree of freedom of rotation with respect to the fourth link 84.
As shown in fig. 1, the second branch chain group 8 further includes: and a second link 85, wherein the second link 85 is an elastic member and is disposed between the third link arm 81 and the fourth link arm 82 in a stretched manner. Therefore, the second connecting member 85 can generate a certain pre-tightening force on the third branch link arm 81 and the fourth branch link arm 82, so that the operation stability of the second branch link group 8 is improved.
Further, the second link 85 includes a plurality of links and is spaced apart along the length of the third link arm 81. The arrangement of the second connecting members 85 can further increase the pre-tightening force between the third branch link arm 81 and the fourth branch link arm 82, thereby further improving the operation stability of the second branch link group 8.
In the second embodiment, as shown in fig. 4, the first branch chain group 7 includes: fifth branch chain arm a1, sixth branch chain arm a2, fifth link a3 and sixth link a 4. Corresponding numbering of the remaining structures in fig. 4 is the same as in fig. 1. Fifth branch chain arm a1 and sixth branch chain arm a2 are parallel to each other. This is advantageous to further increase the rigidity of the first branch link group 7 and to improve the transmission synchronism of the fifth branch link arm a1 and the sixth branch link arm a 2.
As shown in fig. 4, both ends of the fifth link a3 are connected between the upper end of the fifth branched chain arm a1 and the upper end of the sixth branched chain arm a2, respectively, and the fifth link a3 is pivotally connected to the corresponding active arm 21.
Both ends of the sixth link a4 are connected between the lower end of the fifth chain arm a1 and the lower end of the sixth chain arm a2, respectively, and the sixth link a4 is pivotally connected to the corresponding connecting portion 31.
Specifically, the two ends of the fifth link a3 are connected to the fifth chain arm a1 and the sixth chain arm a2 through revolute pairs. It will be appreciated that the fifth and sixth arms a1 and a2 have respective degrees of rotational freedom relative to the fifth link a3 by virtue of the revolute pair connections.
Both ends of the sixth link a4 are connected with the fifth chain arm a1 and the sixth chain arm a2 through revolute pairs. The fifth chain arm a1 and the sixth chain arm a2 thus have a corresponding rotational degree of freedom with respect to the sixth link a 4.
Further, the pair axis of rotation at both ends of the fifth link a3 and the pair axis of rotation at both ends of the sixth link a4 are both parallel to each other.
In the third embodiment, as shown in fig. 5, the second branch chain group 8 includes: a seventh branched link arm b1, an eighth branched link arm b2, a seventh link b3, and an eighth link b 4. Corresponding numbering of the remaining structures in fig. 5 is the same as in fig. 1. The seventh branch link arm b1 and the eighth branch link arm b2 are parallel to each other. This is advantageous to further increase the rigidity of the second branch chain group 8 and improve the transmission synchronism of the seventh branch chain arm b1 and the eighth branch chain arm b 2.
As shown in fig. 5, both ends of the seventh link b3 are connected between the upper end of the seventh branched chain arm b1 and the upper end of the eighth branched chain arm b2, respectively, and the seventh link b3 is pivotally connected to the corresponding active arm 21.
Both ends of the eighth link b4 are respectively connected between the lower end of the seventh link arm b1 and the lower end of the eighth link arm b2, and the eighth link b4 is pivotally connected to the twisting part 6.
Specifically, the two ends of the seventh link b3 are connected to the seventh branched chain arm b1 and the eighth branched chain arm b2 through revolute pairs. It can be understood that the seventh chain arm b1 and the eighth chain arm b2 have corresponding rotational degrees of freedom with respect to the seventh link b3 through the revolute pair connection.
The two ends of the eighth link b4 are connected with the seventh chain arm b1 and the eighth chain arm b2 through revolute pairs. The seventh chain arm b1 and the eighth chain arm b2 thus have a corresponding rotational degree of freedom with respect to the eighth link b 4.
Further, the pair axis of rotation of both ends of the seventh link b3 and the pair axis of rotation of both ends of the eighth link b4 are parallel to each other.
In the fourth embodiment, as shown in fig. 6, the second branch chain group 8 includes: ninth branch link arm c 1. Corresponding numbering of the remaining structures in fig. 6 is the same as in fig. 1. The upper end of the ninth link arm c1 is connected to the corresponding active arm 21 by a hook joint. It will be appreciated that the active arm 21 may be transferred to the ninth articulated arm c1 by means of a hook joint.
The lower end of the ninth link arm c1 is connected to the scrubbing portion 6 by a hook hinge. The ninth link arm c1 can be transmitted to the rolling part 6 by means of a hook hinge connection.
Further, the revolute pairs in the two hooke joints are parallel to each other.
Alternatively, one of the two hooke's joints may be replaced by a ball, which can also achieve the function of stable transmission, and the connection form between the upper end of the ninth link arm c1 and the corresponding active arm 21 and between the lower end of the ninth link arm c1 and the twisting part 6 is not particularly limited.
Alternatively, the second branched chain group 8 may be replaced with any group of branched chains that can form a six-degree-of-freedom unconstrained branched chain together with the corresponding active arm 21.
A high-speed parallel robot 100 in one embodiment of the present invention is described below with reference to fig. 1-3.
According to the utility model discloses high-speed parallel robot 100 of first embodiment includes: the device comprises a fixed platform 1, four driving devices 2, a movable platform 3, gears, an end effector 5, a twisting part 6, three groups of first branch chain groups 7 and three groups of second branch chain groups 8.
Four driving devices 2 are arranged on the fixed platform 1, each driving device 2 comprises an active arm 21 and a driving unit 22 for driving the active arm 21 to pivot, and the driving units 22 are arranged at intervals around the center of the fixed platform 1 in the circumferential direction.
The movable platform 3 is arranged below the fixed platform 1, the movable platform 3 comprises a plurality of connecting parts 31, and the number of the connecting parts 31 is three.
The gear is rotatably arranged in the middle of the movable platform 3.
The end effector 5 is fixedly connected with the gear.
The twisting part 6 is arranged on the movable platform 3 in a sliding way in the horizontal plane, and a guide structure 9 is arranged between the twisting part 6 and the movable platform 3. The part of the twisting part 6 matched with the gear is formed into a rack which can drive the gear to rotate, wherein the three connecting parts 31 and the twisting part 6 are arranged at intervals around the center circumference of the movable platform 3.
The three first branch chain groups 7 are respectively connected between the three driving arms 21 and the three connecting portions 31 in a one-to-one correspondence. The first branch chain group 7 includes: a first link arm 71, a second link arm 72, a first link 73, a second link 74, and a first link 75. The first and second link arms 71 and 72 are parallel to each other. Both ends of the first link 73 are connected between the upper end of the first branched link arm 71 and the upper end of the second branched link arm 72, and the first link 73 is fixedly connected to the corresponding active arm 21. Both ends of the second link 74 are connected between the lower end of the first branch link arm 71 and the lower end of the second branch link arm 72, and the second link 74 is fixedly connected to the corresponding connecting portion 31. The two ends of the first link 73 are matched with the first and second branch link arms 71 and 72 through ball-and-socket and ball-head structures respectively. The two ends of the second connecting rod 74 are matched with the first and second branch chain arms 71 and 72 through ball-and-socket and ball-head structures respectively. The first link 75 is an elastic member and is disposed between the first link arm 71 and the second link arm 72 in tension. The first links 75 are two and spaced apart along the length of the first link arm 71.
The second branch chain group 8 is connected between one of the driving arms 21 and the twisting part 6. The second branch chain group 8 includes: a third branched link arm 81, a fourth branched link arm 82, a third link 83, a fourth link 84, and a second link 85. The third and fourth branched link arms 81 and 82 are parallel to each other. Both ends of the third link 83 are connected between the upper end of the third branched link arm 81 and the upper end of the fourth branched link arm 82, and the third link 83 is fixedly connected to the corresponding active arm 21. Both ends of the fourth connecting rod 84 are connected between the lower end of the third branched chain arm 81 and the lower end of the fourth branched chain arm 82, and the fourth connecting rod 84 is fixedly connected with the twisting part 6. The two ends of the third connecting rod 83 are matched with the third branch chain arm 81 and the fourth branch chain arm 82 through ball-and-socket and ball-head structures respectively. The two ends of the fourth connecting rod 84 are matched with the third branch chain arm 81 and the fourth branch chain arm 82 through ball-and-socket and ball-head structures respectively. The second link 85 is an elastic member and is provided between the third link arm 81 and the fourth link arm 82 in tension. The second link 85 includes two and is spaced apart along the length of the third link arm 81.
Other configurations, such as control devices and the like, and operations of the high-speed parallel robot 100 according to the embodiment of the present invention are known to those skilled in the art and will not be described in detail herein.
In the description herein, references to the description of the terms "embodiment," "example," 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 do not necessarily 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.
While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.
Claims (9)
1. A high-speed parallel robot with decoupled horizontal rubbing rotation and moving freedom degree is characterized by comprising:
fixing a platform;
the driving devices are arranged on the fixed platform, each driving device comprises an active arm and a driving unit for driving the active arm to pivot, and the driving units are arranged at intervals around the center of the fixed platform in the circumferential direction;
the movable platform is arranged below the fixed platform and comprises a plurality of connecting parts, and the number of the connecting parts is one less than that of the driving arms;
the rotating part is rotatably arranged in the middle of the movable platform;
the end effector is fixedly connected with the rotating part;
the twisting part can drive the rotating part to rotate around a vertical shaft, and the connecting parts and the twisting part are arranged at intervals around the center of the moving platform in the circumferential direction;
a plurality of first branch chain groups, which are respectively connected between the plurality of driving arms and the plurality of connecting parts in a one-to-one correspondence manner;
and the second branched chain group is connected between one of the driving arms and the twisting part.
2. The horizontally-scrubbing rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 1, wherein said first set of links comprises:
a first branched arm and a second branched arm, the first branched arm and the second branched arm being parallel to each other;
the two ends of the first connecting rod are respectively connected to the upper end of the first branch chain arm and the upper end of the second branch chain arm in a matched mode through a ball socket and a ball head structure, and the first connecting rod is fixedly connected with the corresponding driving arm;
two ends of the second connecting rod are respectively connected to the lower end of the first branch chain arm and the lower end of the second branch chain arm in a matched manner through a ball socket and a ball head structure, and the second connecting rod is fixedly connected with the corresponding connecting part;
the first connecting piece is an elastic piece and is arranged between the first branched chain arm and the second branched chain arm in a stretching mode, and the first connecting piece comprises a plurality of first connecting pieces which are arranged along the length direction of the first branched chain arm at intervals.
3. The horizontally-twisting rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 1, wherein the second set of branches comprises:
a third branched arm and a fourth branched arm, the third branched arm and the fourth branched arm being parallel to each other;
the two ends of the third connecting rod are respectively connected to the upper end of the third branch chain arm and the upper end of the fourth branch chain arm in a matched manner through a ball socket and a ball head structure, and the third connecting rod is fixedly connected with the corresponding driving arm;
two ends of the fourth connecting rod are respectively connected to the lower end of the third branch chain arm and the lower end of the fourth branch chain arm in a matched manner through a ball socket and a ball head structure, and the fourth connecting rod is fixedly connected with the twisting part;
the second connecting piece is an elastic piece and is arranged between the third branched chain arm and the fourth branched chain arm in a stretching mode, and the second connecting piece comprises a plurality of second connecting pieces which are arranged at intervals along the length direction of the third branched chain arm.
4. The horizontally-scrubbing rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 1, wherein said first set of links comprises:
a fifth branched arm and a sixth branched arm, the fifth branched arm and the sixth branched arm being parallel to each other;
the two ends of the fifth connecting rod are respectively connected to the upper end of the fifth branch chain arm and the upper end of the sixth branch chain arm through revolute pairs, and the fifth connecting rod is connected with the corresponding driving arm in a pivoting mode;
the two ends of the sixth connecting rod are respectively connected to the lower end of the fifth branch chain arm and the lower end of the sixth branch chain arm through revolute pairs, and the sixth connecting rod is connected with the corresponding connecting part in a pivoting mode;
and the axes of the rotation pair at the two ends of the fifth connecting rod and the axes of the rotation pair at the two ends of the sixth connecting rod are parallel to each other.
5. The horizontally-twisting rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 1, wherein the second set of branches comprises:
a seventh branched arm and an eighth branched arm, the seventh branched arm and the eighth branched arm being parallel to each other;
two ends of the seventh connecting rod are connected to the upper end of the seventh branched chain arm and the upper end of the eighth branched chain arm through revolute pairs respectively, and the seventh connecting rod is connected with the corresponding driving arm in a pivoting mode;
two ends of the eighth connecting rod are respectively connected to the lower end of the seventh branch chain arm and the lower end of the eighth branch chain arm through revolute pairs, and the eighth connecting rod is connected with the twisting part in a pivoting mode;
and the axes of the rotation pair at the two ends of the seventh connecting rod and the axes of the rotation pair at the two ends of the eighth connecting rod are parallel to each other.
6. The horizontally-twisting rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 1, wherein the second set of branches comprises:
the upper end of the ninth branch link arm is connected with the corresponding driving arm through a Hooke hinge, and the lower end of the ninth branch link arm is connected with the twisting part through a Hooke hinge; the revolute pairs in the two hook joints are parallel to each other.
7. The high-speed parallel robot with decoupled horizontal twisting rotation and moving freedom according to claim 1, wherein the rotating part is a gear, and the part of the twisting part matched with the rotating part is formed into a rack.
8. The horizontally-twisting rotational and translational degree-of-freedom decoupled high-speed parallel robot according to claim 1, wherein a guide structure is provided between the movable platform and the twisting part.
9. The horizontally-scrubbing rotational-and-translational-degree-of-freedom decoupled high-speed parallel robot of claim 6, wherein one of said two hooke joints is replaced with a ball joint.
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CN111975749A (en) * | 2020-07-29 | 2020-11-24 | 烟台清科嘉机器人联合研究院有限公司 | Horizontal rubbing type high-speed parallel robot with decoupled rotation and movement freedom degrees |
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CN111975749A (en) * | 2020-07-29 | 2020-11-24 | 烟台清科嘉机器人联合研究院有限公司 | Horizontal rubbing type high-speed parallel robot with decoupled rotation and movement freedom degrees |
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