CN217493270U - Six heavy load assembly manipulators with hand dynamics perception ability - Google Patents

Abstract

The utility model relates to a six heavy load assembly manipulators with staff dynamics perception ability, including the Y axle system of establishing on the workshop working face, suspend X axle system on the Y axle system and set gradually Z axle system, U axle system, V axle system, W axle system on the X axle system, Z axle system, U axle system, V axle system, W axle system realize the movement of work piece X to along with X axle motion and move, Y axle system drive X axle system, Z axle system, U axle system, V axle system, W axle system motion realize the movement and adjustment of work piece Y to; the Y-axis system, the X-axis system, the Z-axis system, the U-axis system, the V-axis system and the W-axis system are all electrically connected with the control system, the perception of assembly resistance in the intelligent assembly process of the workpiece can be equivalent to the perception of human hand force during the process of assembling the workpiece in the X-direction and Y-direction movement processes, a foundation is laid for the control of assembly quality, the self-learning capacity of the control system is adopted, and the precision and the accuracy of the assembled workpiece are improved.

Description

Six heavy load assembly manipulators with hand dynamics perception ability

Technical Field

The utility model belongs to intelligent assembly machinery in the production of heavy engineering machine tool product equips the field, relates to a six heavy load assembly manipulators that have staff dynamics perception ability, especially relates to the intelligent multi-axis manipulator when the equipment assembly of frame under the relevant in the heavy engineering machine tool assembly.

Background

With the advance of intelligent manufacturing test point demonstration factories of the Ministry of national industry and informatization and the development requirements of national intelligent manufacturing, the intelligent production of engineering mechanical equipment, lighthouse factories, black light production lines and the like are inevitable; at present, the assembly lines of heavy products (the self weight of the heavy products exceeds 100-180 tons) with the properties of multiple varieties and small batch production, which have not very large capacity but various varieties and specifications, such as piling machinery, trenchless machinery, energy drilling and mining machinery, mine tunnel equipment and the like, have the key factor of improving the production process level, namely the automation level and the intelligent management degree of the carrying equipment of the main line logistics.

At present, large heavy-duty engineering mechanical equipment such as piling machinery, trenchless machinery, energy drilling and mining machinery, mine tunnel equipment and the like are all lower frames based on an H-shaped chassis, and a combined upper frame and a special working machine form a whole machine. The lower frame comprises an H-shaped chassis (the periphery of the supporting legs of the H frame is a processing wear-resistant surface), an extended hydraulic oil cylinder, a workpiece (the surface of the workpiece matched with the supporting legs of the H frame is a rough surface of a welding part, the assembly interval is about 1-2 mm), a crawler and the like.

The traditional assembly process is as follows: firstly, installing the extending oil cylinders and the matched hydraulic pipelines in the four square supporting leg cavities of the H frame to complete the assembly of the components of the H frame; then the assembly of the workpiece beam body, the speed reducer, the driving wheel assembly, the tension wheel, the guide device, the bearing wheel and the rail clamping device is completed; then completing the part assembly of the workpiece and the crawler; and finally, assembling the frame. The typical assembly of the combined frame is to fix an H frame on a support on the ground of a workshop, suspend a workpiece on one side to one side of the H frame by a double-hook traveling crane together, manually adjust the posture of the workpiece by manual observation, manually push the workpiece by hands, repeatedly adjust the posture of the workpiece, try to push or strongly impact to push or strongly beat to push the workpiece to two supporting feet of the H frame for assembly until the assembly of the workpiece on one side and the two supporting feet on one side of the H frame is finished, and then finish the connection of the extension oil cylinder and the workpiece. And repeating the operation flow to complete the assembly of the workpiece on the other side and the H frame. The frame combining assembly process is completed by 2-3 persons and the common effort of the universal hoisting device and the lifting appliance, and the whole assembly process is completed by manpower. The method has the advantages that: 1. the assembly is carried out by hands, the quality problem of the matching hole of the workpiece can be found in the assembly process, manual trimming and adjustment can be carried out in time, special assembly tools are not needed, and the investment and use cost is low; 2. the assembly adaptability is strong, and the production of various products can be met; 3. the use field is small. But the disadvantages are: 1. the labor is more; 2. the assembly operation is carried out under a crane or even under a lifted workpiece, so that the safety is low and the potential safety hazard is large; 3. the assembly condition cannot be directly observed and clarified, and the impact type propulsion or powerful propulsion type trial assembly mode is often adopted, so that the supporting surface of the supporting leg on the H frame is easily damaged, and the later use is influenced; 4. the assembly operation experience requirements and the safety responsibility requirements of operators are high; 5. the integral assembly is discordant: after the workpieces on one side are assembled, the inclination angle and the torsion angle of the supporting leg of the H frame on the other side are changed inconstant, so that the assembly difficulty of the workpieces on the other side is increased, the workpieces are not easy to assemble, and most of the workpieces are assembled only by impact and repeated trial propulsion or forced propulsion; 6. the assembly quality is not high; production management and control are inconvenient; 7. the efficiency is unstable, the production is difficult to organize and arrange, and the requirements of the assembly production line of a modern factory cannot be met; 8. the assembly process and the result are not digitally recorded, and the filing information is deficient.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses a there is the problem that assembly quality is not high, can't realize intelligent assembly, assembly precision is low when the equipment assembly of solving current lower frame, provides a six heavy load assembly machines hand with staff dynamics perception ability.

In order to achieve the above purpose, the utility model provides a following technical scheme:

a six-axis heavy-load assembly manipulator with hand strength sensing capability comprises a Y-axis system, an X-axis system, a Z-axis system, a U-axis system, a V-axis system and a W-axis system, wherein the Y-axis system is arranged on a working surface of a workshop, the X-axis system is suspended on the Y-axis system, and the Z-axis system, the U-axis system, the V-axis system and the W-axis system are sequentially arranged on the X-axis system;

the X-axis system and the Y-axis system are supported in an air floatation mode, a plurality of sets of force sensors are assembled in the X direction and the Y direction, the X direction and the Y direction are low-friction guide, the Y-axis system, the X-axis system, the Z-axis system, the U-axis system, the V-axis system and the W-axis system are all electrically connected with a control system, and the control system is composed of a driving control system, a communication system, a detection system, a virtual workpiece attitude control system, an intelligent image generation system and a management system.

The beneficial effect of this basic scheme lies in: the X-axis system and the Y-axis system are supported in an air floatation mode, low-friction guiding is performed in the X-direction and Y-direction movement process, the perceptibility of assembly resistance in the intelligent assembly process of the workpiece is equivalent to the perceptibility of human hand force during human assembly, and the assembly quality is controlled and improved; the force sensor can detect and feed back the assembly resistance of different assembly positions in real time, and the X-direction and Y-direction intelligent adjustment of the workpiece posture can realize intelligent assembly; the assembly precision and accuracy are improved through the control system.

Furthermore, the Y-axis system comprises Y-axis bases arranged at two ends of the working surface of the workshop, a Y-axis air floatation device fixed on the Y-axis base, a Y-axis driving device fixed on the Y-axis air floatation device, a Y-axis sliding table X-axis base and a Y-axis force sensor arranged on the Y-axis driving device. Has the advantages that: during assembly, the Y-axis air flotation device is used for ventilating and suspending on the Y-axis base, the Y-axis air flotation device is used for conveying to the Y-axis base in the Y direction, and the force in different directions is tested and fed back through the four sets of force sensors.

Furthermore, the X-axis system comprises an X-axis air floatation device, an X-axis driving device, an X-axis sliding table Z-axis base and an X-axis force sensor, wherein the X-axis air floatation device, the X-axis driving device and the X-axis force sensor are arranged on the X-axis base of the Y-axis sliding table in the Y-axis system. Has the beneficial effects that: the X-axis air flotation device is suspended on the X-axis base of the Y-axis sliding table in a ventilation mode, the X-axis air flotation device is transported in the X direction under the action of the X-axis driving device, and the force in different directions is tested and fed back through four sets of force sensors.

Furthermore, the Z-axis system is arranged on the Z-axis base of the X-axis sliding table and comprises a Z-axis guide driving device fixed on the Z-axis base of the X-axis sliding table, a Z-axis sliding table U-axis base fixed on the Z-axis guide driving device and a guide mechanism matched with the Z-axis sliding table U-axis base. Has the advantages that: the stroke control and detection feedback in the Z direction is taken from the Z axis guided drive.

Furthermore, the U-axis system is arranged on a U-axis base of the Z-axis sliding table and comprises a U-axis support and driving device fixed on the U-axis base of the Z-axis sliding table and a V & W-axis base fixed on the U-axis support and driving device.

Furthermore, a plane rotary supporting structure is adopted for supporting the U shaft; the driving device adopts a servo driving device. Has the advantages that: the detection feedback of the turning angle is taken from the driving device.

Furthermore, the V-axis system is arranged on the U-axis reloading platform V & W-axis base and comprises a V-axis swinging fork frame arranged on the U-axis reloading platform V & W-axis base, a guide and support system of the V-axis swinging fork frame, a V-axis limiter and a V-axis driving device. Has the advantages that: the V-axis swing fork swings in a certain range under the action of the V-axis driving device, the maximum swing angle is limited by the V-axis limiter, and meanwhile, the V-axis limiter is also used for the safety protection of the V-axis; the V-axis driving device adopts servo driving, and the control and signal feedback of the swing angle are obtained from the V-axis driving device.

Further, the W-axis system is arranged on the U-axis reloading platform V & W-axis base and comprises a W-axis swinging fork frame arranged on the U-axis reloading platform V & W-axis base, a guide and support system of the W-axis swinging fork frame, a W-axis limiter and a W-axis driving device. Has the advantages that: the W-axis swing fork swings in a certain range under the action of the W-axis driving device, the maximum swing angle is limited by the W-axis limiter, meanwhile, the W-axis limiter is also used as the W-axis driving device for safety protection of the W-axis and adopts servo driving, and the control and signal feedback of the swing angle are obtained from the W-axis driving device.

Furthermore, the V-axis system and the W-axis system share a U-axis reloading platform V & W-axis base, and workpieces are placed on the V-axis system and the W-axis system.

Furthermore, the Y-direction guide adopts two side surfaces of the Y-axis sliding table and the side wall of the Y-axis base to form low-friction guide, and the X-direction guide adopts two side surfaces of the X-axis sliding table and the side wall of the X-axis base to form low-friction guide.

The beneficial effects of the utility model reside in that:

1. the utility model discloses a six heavy load assembly machines hands with staff dynamics perception ability, X axle system, Y axle system adopt the air supporting mode to support, and the frictional force control in X to Y to the motion process is in the scope of staff's power, can realize that the perception degree of the assembly resistance in the work piece intelligence assembly process is equivalent to the perception degree of the staff's power when the people assembled, have laid a good foundation to the control of assembly quality; by adopting the self-learning capability of the control system, the attitude parameters in the assembly process and the self-learned parameters in the clamping process are adjusted, and the precision and accuracy of the assembled workpiece are improved.

2. The utility model discloses a six heavy load assembly manipulators with staff dynamics perception ability adopts X to, Y to assemble and has disposed the force transducer that can real-time detection and the assembly resistance of different assembly positions of feedback respectively, the intelligent regulation work piece gesture, and monitoring control assembly resistance can realize intelligent assembly in the staff power scope; the problem that the posture cannot be adjusted by manual assembly due to the fact that the postures of the track and the workpiece body are intermittent and large assembling holes is strange is solved through an intelligent adjusting control mode.

3. The utility model discloses a six heavy load assembly manipulator with hand strength perceptibility, which adopts digital technology to virtualize the attitude parameters and images of the workpiece on a human-computer interface, and visually compares the attitude parameters and images during manual remote control assembly; the data acquisition of the assembly process, the relevant data acquisition of assembly output quality promotes the management and control ability that the assembly line becomes more meticulous greatly.

4. The utility model discloses a six heavy load assembly manipulator with staff dynamics perception ability, which adopts six-freedom heavy load assembly manipulator structure, six-freedom combination adjusts the workpiece attitude, one set of equipment can satisfy the assembly requirement of multiple varieties; meanwhile, a mode that the V shaft and the W shaft share the base is adopted, the problem that an assembly workpiece (workpiece) is distorted in the X direction and the Y direction is solved, and the problem that assembly holes are different in height is solved through the combined action of the V shaft and the W shaft.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention may be realized and attained by the means of the instrumentalities and/or combinations particularly pointed out in the appended claims.

Drawings

For the purposes of promoting a better understanding of the objects, features and advantages of the invention, reference will now be made to the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic structural view of a six-axis heavy-duty assembly manipulator with hand force sensing capability according to the present invention;

FIG. 2 is a top view of the six-axis heavy-duty assembly robot with hand force sensing capability of the present invention;

FIG. 3 is a schematic structural diagram of the six-axis heavy-duty assembly manipulator frame assembling machine with hand force sensing capability of the present invention;

fig. 4 is a top view of the six-axis heavy-duty assembly manipulator frame assembly machine with hand force sensing capability of the present invention;

fig. 5 is a schematic structural view of a lower frame composed of an H-shaped chassis and a workpiece.

Reference numerals: a Y-axis base 1, a Y-axis air-floating device 2, a Y-axis driving device I3, a Y-axis slipway X-axis base 4, an X-axis air-floating device 5, an X-axis slipway Z-axis base 6, a Z-axis guiding and driving device 7, a Y-axis driving device II 8, a Z-axis slipway U-axis base 9, a U-axis supporting and driving device 10, a U-axis reinstallation platform V & W-axis base 11, a workpiece antiskid supporting plate 12, an X-axis force sensor I13, a Y-axis force sensor I14 and an X-axis driving device I15, the device comprises a W-axis limiter 16, a W-axis driving device 17, a W-axis swinging fork frame 18, a Y-axis force sensor II 19, an X-axis force sensor II 20, a V-axis swinging fork frame 21, an X-axis driving device II 22, a V-axis limiter 23, a V-axis driving device 24, an X-axis force sensor III 25, a Y-axis force sensor III 26, a Y-axis force sensor IV 27, an X-axis force sensor IV 28, a control system 29 and a workpiece 30.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention. It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the features in the following embodiments and examples may be combined with each other without conflict.

Wherein the showings are for the purpose of illustrating the invention only and not for the purpose of limiting the same, and in which there is shown by way of illustration only and not in any way limiting the scope of the invention; for a better understanding of the embodiments of the present invention, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar parts; in the description of the present invention, it should be understood that if there are the terms "upper", "lower", "left", "right", "front", "back", etc., indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of the description, but not for indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore the terms describing the positional relationship in the drawings are only used for illustrative purposes, and should not be construed as limitations of the present invention, and it will be understood that specific meanings of the above terms can be understood by those skilled in the art according to specific situations.

As shown in fig. 1 to 4, the six-axis heavy-load assembly manipulator with human hand strength sensing capability comprises a Y-axis system, an X-axis system, a Z-axis system, a U-axis system, a V-axis system and a W-axis system, which are arranged on a working surface of a workshop, and are suspended on the Y-axis system, and the Z-axis system, the U-axis system, the V-axis system and the W-axis system are sequentially arranged on the X-axis system, and the Z-axis system, the U-axis system, the V-axis system and the W-axis system move along with the X-axis to realize the movement and adjustment of a workpiece in the X-axis direction; the Y-axis system, the X-axis system, the Z-axis system, the U-axis system, the V-axis system and the W-axis system are all electrically connected with a control system 29, the control system is composed of a driving control system, a communication system, a detection system, a virtual workpiece attitude control system, an intelligent image generation system and a management system, and attitude parameters in the assembly process are displayed through the control system.

The Y-axis system comprises Y-axis bases 1 arranged at two ends of a workshop working face, a set of Y-axis air flotation device 2 fixed on the Y-axis base 1, a Y-axis driving device I3 and a Y-axis driving device II 8 fixed on the Y-axis air flotation device 2, a Y-axis sliding table X-axis base 4 and four sets of Y-axis force sensors arranged on the Y-axis driving device 3, namely a Y-axis force sensor I14, a Y-axis force sensor II 19, a Y-axis force sensor III 26 and a Y-axis force sensor IV 27, and is located at the bottommost layer, is a foundation of a six-axis heavy-load assembly manipulator and bears all the weight of other five-axis systems. During operation, the Y-axis air floatation device 2 is used for ventilating to work and suspending on the Y-axis base 1, motion in the Y direction is achieved under the action of the Y-axis driving device I3 and the Y-axis driving device II 8, the magnitude and the direction of forces in different directions (such as + Y1, + Y2, -Y1 and-Y2) are tested and fed back through four sets of force sensors, the Y-axis system drives other five axes to achieve motion and adjustment in the Y direction, and position detection signals in the Y direction are obtained from a servo system.

The Y-axis system realizes forward and backward movement: firstly, the Y-axis air floatation device 2 is started to be in a working state, so that the sliding table of the Y-axis system is suspended. The forward and backward movement of the Y axis is realized by the way that a chain with two ends fixed on the X axis base 4 of the Y axis sliding table bypasses chain wheels on output shafts of a Y axis driving device I3 and a Y axis driving device II 8 through two sets of servo drive controlled speed reducers fixed on the X axis base 4 of the Y axis sliding table through two inertia chain wheels, and a Y axis force sensor I14, a Y axis force sensor II 19, a Y axis force sensor III 26 and a Y axis force sensor IV 27 are respectively arranged at two ends of the chain. And a servo motor is started to operate, and the Y-axis sliding table and equipment on the upper part of the Y-axis sliding table are pulled to advance by the rotation of the output shaft end chain wheel, so that the + Y-direction operation is realized. The no-load resistance and the assembly resistance during the forward movement can be obtained by the sum of the forces output by the two sets of force sensors in the forward direction. The servo system sends Y-direction position signals to the control system according to sampling requirements, the two sets of force sensors output force magnitude and difference signals simultaneously, and the system can judge whether the attitude of the workpiece is combined with process requirements during assembly according to the position signals, the force magnitude and the difference signals, so that relevant information is sent to the control system, the control system can quickly respond to the position signals, motion control signals and attitude adjustment information are sent out, and a virtual workpiece attitude diagram is output simultaneously. According to signals of a control system, the Y-axis driving device I3 and the Y-axis driving device II 8 automatically realize the movements of speed reduction stopping, continuous advancing, backward running and the like, and meet the movement requirements and position requirements of the assembly process in the Y direction. The servo driving system runs in the reverse direction to realize the backward movement in the-Y direction. After the sliding table of the Y axis returns to the original position, the operation of the Y axis air floating device 2 may be stopped.

The X-axis system comprises an X-axis driving device I15 and an X-axis driving device II 22 which are arranged on a Y-axis sliding table X-axis base 4 in the Y-axis system, an X-axis sliding table Z-axis base 6 and four sets of X-axis force sensors which are arranged on the X-axis driving device I15 and the X-axis driving device II 22 and are respectively an X-axis force sensor I13, an X-axis force sensor II 20, an X-axis force sensor III 25 and an X-axis force sensor IV 28, the X-axis system is positioned on the Y-axis system, the X-axis system is suspended on the Y-axis sliding table X-axis base 4 through the ventilation work of an X-axis air floating device 5 during work, the movement in the X direction is realized under the action of the two sets of driving devices, the magnitude and the direction of the force in different directions (such as + X1, + X2, -X1 and-X2) are tested and fed back through the four sets of force sensors, the Z-axis, U-axis, V-axis and W-axis systems are all arranged on the X-axis system, and realize the movement in the X direction along with the movement of the X-axis, the position detection signal in the X direction is taken from a servo system.

The X-axis system realizes forward and backward movement: firstly, the X-axis air floatation device 5 is started to be in a working state, so that the sliding table of the X-axis system is suspended. The forward and backward movement of the X shaft is realized by the way that a chain with two ends fixed on the X shaft base of the Y shaft sliding table 4 bypasses chain wheels on output shafts of an X shaft driving device I15 and an X shaft driving device II 22 through two sets of servo drive controlled speed reducers fixed on a Z shaft base 6 of the X shaft sliding table through two inertia chain wheels, and an X shaft force sensor I13, an X shaft force sensor II 20, an X shaft force sensor III 25 and an X shaft force sensor IV 28 are respectively arranged at two ends of the chain. And starting a servo motor to operate, and driving the X-axis sliding table and equipment on the upper part of the X-axis sliding table to move forward by the rotation of the output shaft end chain wheel to realize the operation in the direction of + X. The no-load resistance and the assembly resistance in the forward motion can be obtained by the sum of the forces output by the two sets of force sensors in the forward direction. The servo system sends X-direction position signals to the control system according to sampling requirements, the two sets of force sensors output force magnitude and difference signals simultaneously, and the system can judge whether the attitude of the workpiece is combined with process requirements during assembly according to the position signals, the force magnitude and the difference signals, so that relevant information is sent to the control system, the control system can quickly respond to the position signals, the attitude adjustment information is sent out, and a virtual workpiece attitude graph is output simultaneously. According to signals of a control system, the X-axis driving device I15 and the X-axis driving device II 22 automatically realize the movements of speed reduction stopping, continuous advancing, backward running and the like, and the movement requirements and the position requirements in the X direction of the assembly process are met. The servo driving system runs in the reverse direction to realize the backward movement in the-X direction. After the sliding table of the X-axis returns to the original position, the operation of the X-axis air floatation device 5 can be stopped.

The Y-direction guide adopts two side surfaces of the sliding table and the side wall of the Y-axis base 1 to form low-friction guide, the X-direction guide adopts two side surfaces of the sliding table and the side wall of the X-axis base 4 of the Y-axis sliding table to form low-friction guide, the X-axis system and the Y-axis system are supported by an air floatation mode, and the friction coefficient in the movement process is as low as 1-5 per mill.

The Z-axis system is arranged on an X-axis sliding table Z-axis base 6 and comprises a Z-axis guiding driving device 7 fixed on the X-axis sliding table Z-axis base 6, a Z-axis sliding table U-axis base 9 fixed on the Z-axis guiding driving device 7 and a four-column guiding mechanism matched with the Z-axis sliding table U-axis base 9, wherein the Z-axis guiding driving device 7 is controlled by a servo system, and Z-direction stroke control and detection feedback are obtained from the servo system.

The Z-axis system realizes lifting movement: the Z-axis motion is mainly used for controlling the height between the assembly space of the workpiece to be assembled and the supporting leg of the H-shaped chassis. According to the type of the received H-shaped chassis, the chassis centering device sends a height instruction, the servo driving device 7 of the Z axis is started, ascends and descends as required, fine adjustment is carried out in place according to the virtual workpiece posture and parameters after the initial placement, and X, Y direction assembling signals are sent. And lifting in real time according to the signals received in the assembly process to meet the requirements of the assembly process.

The U-axis system is arranged on a Z-axis sliding table U-axis base 9 and comprises a U-axis supporting and driving device 10 fixed on the Z-axis sliding table U-axis base 9 and a U-axis repacking table V & W-axis base 11 fixed on the U-axis supporting and driving device 10, and the U-axis support adopts a plane rotary supporting structure; the driving device adopts a servo driving device, and the detection feedback of the rotation angle is obtained from a servo system.

The U-axis system realizes rotary motion: and the rotation motion of the U shaft is used for adjusting the parallelism of an assembly hollow center line of the workpiece to be assembled and the center line of the supporting leg of the H-shaped chassis. And starting the servo driving device 10 of the plane rotary support to operate according to the received signal needing to be adjusted, and adjusting to the required position. And in the assembling process, rotation adjustment is carried out according to the received adjusting signal so as to meet the requirements of the assembling process.

The V-axis system is arranged on a U-axis reloading platform V & W axis base 11 and comprises a V-axis swinging fork frame 21 arranged on the U-axis reloading platform V & W axis base 11, a guide and support system of the V-axis swinging fork frame 21, a V-axis stopper 23 and a V-axis driving device 24, wherein the V-axis swinging fork frame 21 swings within a certain range under the action of the V-axis driving device 24, the maximum swing angle is limited by the V-axis stopper 23, and meanwhile, the V-axis stopper 23 also serves as the safety protection of a V axis; the V-axis drive 24 employs servo drive, and the control of the swing angle and signal feedback are taken from the V-axis drive 24.

The W-axis system is arranged on a V & W-axis base 11 of a U-axis reinstallation platform and comprises a W-axis swing fork frame arranged on the V & W-axis base of the U-axis reinstallation platform, a guide and support system of the W-axis swing fork frame 18, a W-axis limiter 16 and a W-axis driving device, wherein the W-axis swing fork frame swings in a certain range under the action of the W-axis driving device, the maximum swing angle is limited by the W-axis limiter, meanwhile, the W-axis limiter is used as a W-axis safety protection W-axis driving device 17 and adopts servo driving, and the control of the swing angle and signal feedback are obtained from the W-axis driving device 17.

The V-axis system and the W-axis system share one U-axis reloading platform V & W-axis base 11, workpieces 30 are placed on the V-axis system and the W-axis system, and a workpiece anti-skid supporting plate 12 is arranged between the V-axis system and the W-axis system.

The V & W shaft system realizes swing motion: after the workpiece 30 is assembled, the intervals between the crawler teeth and the driving gear, the tension wheel, the bearing wheel and the like on the workpiece are inconsistent, and after the workpiece is assembled, two assembling holes matched with the supporting legs of the H-shaped chassis on the workpiece and a neutral line of an extension part on the inner side of the cantilever initial crawler are not parallel relative to a swinging fork frame supporting the workpiece, so that various distortions can be generated. The respective actions of the V & W axis system are to adjust the workpiece distortion. And the V shaft and the W shaft respectively start respective servo driving devices to do corresponding swinging adjustment movement according to the received control signal or the manual remote operation control signal, so that the central line of the assembly hole is matched with the neutral line of the supporting leg of the H-shaped chassis, and the requirement of the assembly process is met. And adjusting the posture of the workpiece 30 according to the received adjusting signal in the assembly process to meet the requirements of the assembly process. And meanwhile, each shaft system is also respectively provided with limit swing angle limit when the unsafe conditions that the gravity center is deviated due to power failure and workpiece sliding are prevented. The safety and reliability of the assembly process are ensured.

The operation method of the six-axis heavy-load assembly manipulator with the hand strength sensing capability comprises the following two steps:

1. manual remote control operation: and starting an air source to enable the X-axis air floatation device 5 and the Y-axis air floatation device 2 to be in a work preparation state at the original point of the manipulator. And matching the related workpiece 30 assembly according to the H-shaped chassis required to be assembled, manually hoisting the H-shaped chassis on the V & W shaft, and operating the V & W shaft to operate so that the workpiece 30 to be assembled only depends on the rear side of the swing fork. And remotely controlling the X axis and the Y axis according to the H-shaped chassis image and the virtual workpiece attitude image on the human-computer interface to enable the workpiece 30 to be close to the supporting legs of the H-shaped chassis. And the Z shaft is remotely controlled to enable the height to meet the assembly requirement, the U shaft is remotely controlled to enable the axis of the assembly hole in the workpiece 30 to be matched with the axis of the corresponding support leg of the H-shaped chassis, and the V and W shafts are further remotely controlled to adjust the posture of the workpiece to achieve an assembly state. And remotely controlling the X axis to move forwards and observing the force magnitude and difference of the force sensor, and continuously adjusting the posture of the workpiece 30 and remotely controlling the feeding until the assembly is finished. And finally, returning the six-degree-of-freedom heavy-load assembly manipulator to the original point. And closing the X-axis air floatation device 5 and the Y-axis air floatation device 2 and waiting for the next assembly task.

2. Automatic assembly action: and receiving an assembly task, automatically starting an air source, and keeping the original point in a working equipment state. Signaling the workpiece 30 component. The manual hoist workpiece 30 is placed on the swing fork of the V & W axis system. The completion instruction for lifting the workpiece 30 is manually issued. And the manipulator automatically measures and records the original point data of each axis. And automatically approaching the front of the supporting legs of the H-shaped chassis to be assembled according to the received data of the H-shaped chassis. And (3) automatically adjusting the posture of the workpiece, enabling the X-axis and the Y-axis to enter assembly operation, and dynamically adjusting the posture of the workpiece 30 according to the received data of each force sensor until the assembly is finished. And after an assembly completion signal is sent, automatically returning to the original point, closing the air source, enabling the manipulator to be in an original point standby state, and waiting for a next assembly instruction.

The other side workpiece 30 assembly is as described above and can be simultaneously assembled to complete the assembly process as shown in fig. 5.

Finally, the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions, and all of them should be covered by the scope of the claims of the present invention.

Claims (10)

1. A six-axis heavy-load assembly manipulator with hand strength sensing capability is characterized by comprising a Y-axis system, an X-axis system, a Z-axis system, a U-axis system, a V-axis system and a W-axis system, wherein the Y-axis system is arranged on a workshop working surface, the X-axis system is suspended on the Y-axis system, and the Z-axis system, the U-axis system, the V-axis system and the W-axis system are sequentially arranged on the X-axis system;

the X-axis system and the Y-axis system are supported in an air floatation mode, a plurality of sets of force sensors are assembled in the X direction and the Y direction, the X direction and the Y direction are low-friction guide directions, the Y-axis system, the X-axis system, the Z-axis system, the U-axis system, the V-axis system and the W-axis system are all electrically connected with a control system, and the control system is composed of a driving control system, a communication system, a detection system, a virtual workpiece attitude control system, an intelligent image generation system and a management system.

2. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 1, wherein the Y-axis system comprises a Y-axis base installed at both ends of a workshop working surface, an air floating device fixed on the Y-axis base, a Y-axis driving device fixed on the air floating device, a Y-axis sliding table X-axis base, and a Y-axis force sensor installed on the Y-axis driving device.

3. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 1, wherein said X-axis system comprises an X-axis air floating device, an X-axis driving device, an X-axis slipway Z-axis base and an X-axis force sensor mounted on the X-axis driving device, wherein the X-axis air floating device is arranged on the X-axis base of the Y-axis slipway in the Y-axis system.

4. The six-axis heavy-duty assembly manipulator with human hand strength sensing capability of claim 1, wherein the Z-axis system is disposed on the X-axis slipway Z-axis base and comprises a Z-axis guiding driving device fixed on the X-axis slipway Z-axis base, a Z-axis slipway U-axis base fixed on the Z-axis guiding driving device, and a guiding mechanism adapted to the Z-axis slipway U-axis base.

5. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 1, wherein said U-axis system is disposed on a Z-axis slipway U-axis base, and comprises a U-axis support and drive device fixed on the Z-axis slipway U-axis base, and a U-axis reloading table V & W-axis base fixed on the U-axis support and drive device.

6. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 5, wherein said U-axis support is a planar rotary support structure; the driving device adopts a servo driving device.

7. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 1, wherein said V-axis system is disposed on a U-axis reloading station V & W axis base, comprising a V-axis swing fork disposed on the U-axis reloading station V & W axis base, a guidance and support system for the V-axis swing fork, a V-axis stop, a V-axis drive.

8. The six-axis heavy-duty assembly robot with human hand strength sensing capability of claim 1, wherein said W-axis system is disposed on a V & W axis base of a U-axis reloading station, comprising a W-axis swing fork disposed on the V & W axis base of the U-axis reloading station, a guide and support system for the W-axis swing fork, a W-axis stop, and a W-axis drive.

9. The six-axis heavy-duty assembly robot with human hand strength sensing capability of any one of claims 7-8, wherein the V-axis system and the W-axis system share a U-axis repacking station V & W-axis base, and workpieces are placed on the V-axis system and the W-axis system.

10. The six-axis heavy-duty assembly manipulator with manual force sensing capability of claim 1, wherein the Y-direction guidance adopts two side surfaces of a Y-axis sliding table and a side wall of a Y-axis base to form low-friction guidance, and the X-direction guidance adopts two side surfaces of an X-axis sliding table and a side wall of an X-axis base to form low-friction guidance.

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