CN204508205U - A kind of two-way transfer robot of two bars based on parallel principle - Google Patents

Abstract

The utility model discloses a kind of two-way transfer robot of two bars based on parallel principle, it comprises rotary disk, and the side of described rotary disk is provided with rotary disk motor; The top of described rotary disk is provided with complete machine lifting assembly, the top of described complete machine lifting assembly is fixedly installed base plate, one end of described base plate is provided with carriage assembly, described carriage assembly is hinged with Swing Arm and control stalk, the longitudinal hinge-point longitudinal oscillation of described Swing Arm under the driving of longitudinal drive rotating device bottom it, described Swing Arm is laterally hinged with a teeter under the driving of horizontal drive rotating device bottom it; The upper end of described Swing Arm is provided with sucker gripper, and described control stalk all forms the articulated linkage structure of parallelogram in main apparent direction and side-looking direction with described Swing Arm.The handgrip of the utility model transfer robot allows the actuating unit of handgrip sucker maintenance level remain level without the need to arranging in addition, thus reduces cost and save power resource.

Description

A kind of two-way transfer robot of two bars based on parallel principle

Technical field

The utility model relates to Industrial Robot Technology field, relates to a kind of based on parallel principle single armed way moving transfer robot specifically.

Background technology

In developed country, industrial robot automatic production line complete equipment has become main flow robot development prospect and the developing direction in future of automated arm.The industries such as Automotive Industry Abroad, electronic enterprises, construction machinery and equipment use industrial robot automatic production line in a large number, to ensure product design, enhance productivity, avoid a large amount of accident on dutys simultaneously.The use practice of the industrial robot of global many national nearly half a century shows, the universal of industrial robot realizes automated production, improves social production efficiency, the effective means that promotion enterprise and social productive forces develop.At present, single armed swinging mechanical hand on the market, because its mobile alignment is circular arc, handgrip sucker is difficult to the rectilinear movement realizing level, in order to allow handgrip sucker maintenance level, often needing the auxiliary of actuating unit, so also can improve manufacturing cost accordingly.And the stability of single armed is lower, manipulator easily produces and rocks in moving process, has a strong impact on the control accuracy of manipulator, is difficult to the accuracy requirement reaching people.

Therefore, utility model people of the present utility model needs a kind of up-to-date technology of design badly to improve its problem.

Utility model content

The utility model aim to provide a kind of can reduce driving torque can reduce again cost based on parallel principle single armed way moving transfer robot.

For solving the problems of the technologies described above, the technical solution of the utility model is:

Based on the two-way transfer robot of two bars of parallel principle, it comprises rotary disk, and the axes normal of described rotary disk is in horizontal surface, and the side of described rotary disk is provided with the rotary disk motor for driving described rotary disk circumference to rotate, the top of described rotary disk is provided with for the complete machine lifting assembly driving the sucker gripper of described robot vertically to rise or to decline, the top of described complete machine lifting assembly is fixedly installed the base plate of level, one end of described base plate is provided with the carriage assembly for supporting described sucker gripper, described carriage assembly is hinged with Swing Arm and the control stalk for assisting described Swing Arm to swing, the longitudinal hinge-point longitudinal oscillation of described Swing Arm under the driving of longitudinal drive rotating device bottom it, described Swing Arm is laterally hinged with a teeter under the driving of horizontal drive rotating device bottom it, described Swing Arm and described control stalk all upwards extend and be arranged in parallel, the upper end thereof of described Swing Arm has sucker pole pedestal, described sucker pole pedestal is horizontally disposed with, one end away from described Swing Arm of described sucker pole pedestal connects described sucker gripper, described sucker pole pedestal is hinged on the upper end of described Swing Arm by large bar connector alive, the rotation direction that described sucker pole pedestal is lived in connector at described large bar is vertical with the rotation direction of the relative described Swing Arm of described large bar connector alive, described control stalk is provided with two, two described control stalks overlap in the projection of main apparent direction, the both sides of described Swing Arm are laid respectively in the projection in side-looking direction, described control stalk all forms the articulated linkage structure of parallelogram in main apparent direction and side-looking direction with described Swing Arm, one end away from described sucker gripper of described sucker pole pedestal is fixedly connected on the connecting rod between two described control stalk upper ends.

Further, the upper end of two described control stalks is all hinged with little bar connector alive, the axle center place of described little bar connector alive rotates and is provided with shaft coupling, described shaft coupling extends to described Swing Arm side and parallel with described sucker pole pedestal, connected by three axle connecting rods between the free end of two described shaft couplings, described sucker pole pedestal, described shaft coupling are all fixedly connected with described three axle connecting rods.

Further, in side-looking direction, two described control stalks are symmetricly set on the both sides of described Swing Arm.

Further, described horizontal drive rotating device comprises the mair motor be fixed on described base plate, the mouth of described mair motor is connected with retarder, the driving gear for Power output on described retarder engages with the driven gear be set on main shaft, described main shaft is rotatably arranged on described base plate by bearing, one end of described main shaft and the bottom-hinged of described Swing Arm, the articulated structure of described main shaft and described Swing Arm promotes described Swing Arm transverse reciprocating and swings when being suitable for described main axis, and be suitable for described longitudinal drive rotating device and drive described Swing Arm at longitudinal reciprocally swinging.

Further, the below of described main shaft is fixedly connected with clump weight, and described Swing Arm is in extreme lower position perpendicular to the center of gravity of clump weight described during horizontal surface.

Further, described main shaft is supported on described base plate by the framed side wallboard that be arranged in parallel and front wallboard, the bottom of described framed side wallboard and described front wallboard is fixed on described base plate, described bearing for supporting described main shaft is separately fixed at described framed side wallboard and described front wallboard, and described clump weight is arranged between described framed side wallboard and described front wallboard.

Further, described longitudinal driving rotation mechanism comprises the inlet/outlet mechanism actuating device be arranged on above described main shaft, the end that ejects of described inlet/outlet mechanism actuating device links with inlet/outlet mechanism connecting rod support, described inlet/outlet mechanism connecting rod support is slidably arranged on the linear module of inlet/outlet mechanism, described inlet/outlet mechanism connecting rod support is hinged with inlet/outlet mechanism connecting rod, the other end of described inlet/outlet mechanism connecting rod is hinged on described Swing Arm, the hinge-point in the vertical direction of described inlet/outlet mechanism connecting rod and described Swing Arm is higher than the hinge-point of described inlet/outlet mechanism connecting rod support and described inlet/outlet mechanism connecting rod.

Further, the linear module of described inlet/outlet mechanism is linear guides, and described inlet/outlet mechanism connecting rod support is arranged in the rail groove of described linear guides.

Further, described complete machine lifting assembly comprises the lifting motor fixed on the ground, the mouth of described lifting motor is coaxially connected with driving screw mandrel, the axes normal of described driving screw mandrel is arranged in horizontal surface, described driving screw mandrel is provided with the commutator with the screw thread fit on described driving screw mandrel, described commutator is connected with the elevating screw that horizontal direction extends, described commutator is suitable for described driving screw mandrel and turns the rotation of described elevating screw; The thread rotary orientation of the axial midpoint both sides of described elevating screw is contrary, the screw thread that two of described elevating screw are reverse is arranged with the drive block with the screw thread fit of corresponding rotation direction respectively, the upper and lower side of described drive block is hinged with lifting bar respectively, be positioned at the lower surface of upper end thereof at described base plate of two described lifting bars above described elevating screw, the lower end being positioned at two described lifting bars below described elevating screw is hinged on the upper surface of described rotary disk, and four described lifting bars are arranged in " X " shape; When described elevating screw rotates forward, drive two described drive blocks mutually away from, when described elevating screw rotates backward, drive two described drive blocks close to each other.

Further, the lower end of described control stalk is hinged on described carriage assembly, and the hinge-point of described control stalk lower end and the hinge-point of described Swing Arm lower end are positioned on same level line.

Adopt technique scheme, the utility model at least comprises following beneficial effect:

It is described in the utility model based on parallel principle single armed way moving transfer robot,

Between the Swing Arm of the two-way transfer robot of two bars based on parallel principle of the present utility model and control stalk be engaged in longitudinal oscillation and teeter time composition parallelogram sturcutre, under parallelogram effect, the article that handgrip sucker captures can remain level, allow the dynamic rotation mechanism of handgrip sucker maintenance level without the need to arranging in addition, thus reduce cost and save power resource; And by arranging clump weight in the below of main shaft, then effectively can reduce driving torque and reduce driving power, and then save cost and the energy.

Accompanying drawing explanation

Fig. 1 is the front view of the two-way transfer robot of two bars based on parallel principle described in the utility model;

Fig. 2 is the lateral plan of the two-way transfer robot of two bars based on parallel principle described in the utility model;

Fig. 3 is the birds-eye view at Swing Arm of the present utility model and top, control stalk cooperation place;

Fig. 4 is that the K-K of Fig. 3 is to cutaway view;

Fig. 5 is the parallel principle schematic that control stalk of the present utility model is formed with Swing Arm.

Wherein: 1. clump weight, 2. mair motor, 3. base plate, 4. driving gear, 5. retarder, 6. framed side wallboard, 7. driven gear, 8. main shaft, 9. inlet/outlet mechanism actuating device, 10-inlet/outlet mechanism motor cabinet, the linear module of 11. inlet/outlet mechanism, 12. inlet/outlet mechanism connecting rod supports, 13. inlet/outlet mechanism connecting rods, 14. Swing Arm bearings, 15. Swing Arms, 16. large bars connector alive, 17. sucker pole pedestals, 18. 3 axle connecting rods, 19. shaft couplings, 20. little bars connector alive, 21. control stalks, 22. anchor shafts, 23. turnover axles, 24. bearings, 25. carriage assemblies, 26. front wallboards, 27. complete machine lifting assemblies, 28. rotary disks, 29. elevating screws, 30. rotary disk motors, 31. commutators, 32. lifting motors, 33. sucker grippers, 34. drive screw mandrel, 35. drive blocks, 36. lifting bars.

Detailed description of the invention

Below in conjunction with drawings and Examples, the utility model is further illustrated.

As shown in Figures 1 to 5, for meeting the structural representation of a kind of two-way transfer robot of two bars based on parallel principle of the present utility model, the rotation direction for corresponding component that in figure, black arrow represents, wherein it comprises rotary disk 28, the axes normal of described rotary disk 28 is in horizontal surface, the side of described rotary disk 28 is provided with the rotary disk motor 30 for driving described rotary disk 28 circumference to rotate, and described rotary disk motor 30 can drive described rotary disk 28 to rotate positive and negative 360 degree, the top of described rotary disk 28 is provided with the complete machine lifting assembly 27 for driving the sucker gripper 33 of described robot vertically to rise or decline, the top of described complete machine lifting assembly 27 is fixedly installed the base plate 3 of level, one end of described base plate 3 is provided with the carriage assembly 25 for supporting described sucker gripper 33, described carriage assembly 25 is hinged with Swing Arm 15 and the control stalk 21 for assisting described Swing Arm 15 to swing, described Swing Arm 15 is hinged by turnover axle 23, described control stalk 21 is hinged on anchor shaft 22, the longitudinal hinge-point longitudinal oscillation of described Swing Arm 15 under the driving of longitudinal drive rotating device bottom it, described Swing Arm 15 is laterally hinged with a teeter under the driving of horizontal drive rotating device bottom it, described longitudinal hinge-point becomes 90 degree with the described jointed shaft axes intersect be laterally hinged with a little, described Swing Arm 15 all upwards extends with described control stalk 21 and be arranged in parallel, the upper end thereof of described Swing Arm 15 has sucker pole pedestal 17, described sucker pole pedestal is bar shaft-like structure, described sucker pole pedestal 17 is horizontally disposed with, one end away from described Swing Arm 15 of described sucker pole pedestal 17 connects described sucker gripper 33, described sucker pole pedestal 17 is hinged on the upper end of described Swing Arm 15 by large bar connector 16 alive, the rotation direction that described sucker pole pedestal 17 is lived in connector 16 at described large bar is vertical with the direction that described large bar connector 16 alive rotates around Swing Arm 16, the rotation direction that described sucker pole pedestal 17 is lived in connector 16 at described large bar is vertical with the rotation direction of the relative described Swing Arm 15 of described large bar connector 16 alive, described control stalk 21 is provided with two, two described control stalks 21 overlap (see Fig. 1) in the projection of main apparent direction, the both sides (see Fig. 2) of described Swing Arm 15 are laid respectively in the projection in side-looking direction, and be symmetrical arranged, the lower end of described control stalk 21 is fixed on carriage assembly 25, the hinge-point of described control stalk 21 lower end and the hinge-point of described Swing Arm 15 lower end are positioned on same level line, described control stalk 21 all forms the articulated linkage structure of parallelogram with described Swing Arm 15 in main apparent direction and side-looking direction, and one end away from described sucker gripper 33 of described sucker pole pedestal 17 is fixedly connected on the connecting rod between two described control stalk 21 upper ends.Between the Swing Arm of the present embodiment and control stalk be engaged in longitudinal oscillation (direction that swings in Fig. 2 is for longitudinally) and teeter (direction that swings in Fig. 1) time form parallelogram sturcutre, under parallelogram effect, the article that handgrip sucker captures can remain level, allow the dynamic rotation mechanism of handgrip sucker maintenance level without the need to arranging in addition, thus reduce cost and save power resource.

In the present embodiment, the upper end of two described control stalks 21 is all hinged with little bar connector 20 alive, the axle center place of described little bar connector 20 alive rotates and is provided with shaft coupling 19, described shaft coupling 19 extends to described Swing Arm 15 side and parallel with described sucker pole pedestal 17, connected by three axle connecting rods 18 between the free end (this free end is between Swing Arm and control stalk) of two described shaft couplings 19, described sucker pole pedestal 17, described shaft coupling 19 are all fixedly connected with described three axle connecting rods 18.

In the present embodiment, described horizontal drive rotating device comprises the mair motor 2 be fixed on described base plate 3, the mouth of described mair motor 2 is connected with retarder 5, the driving gear 4 for Power output on described retarder 5 engages with the driven gear 7 be set on main shaft 8, described main shaft 8 is by large bar connector alive rotatably fixed described base plate 3, one end of described main shaft 8 and the bottom-hinged of described Swing Arm 15, described main shaft 8 is suitable for promoting described Swing Arm 15 transverse reciprocating when described main shaft 8 rotates with the articulated structure of described Swing Arm 15 and swings, and be suitable for described longitudinal drive rotating device and drive described Swing Arm 15 at longitudinal reciprocally swinging, see Fig. 1, the left end of described main shaft 8 and hinged of described Swing Arm 15 are the plane of vertical direction, this perpendicular can ensure the teeter (swing of Fig. 1 left and right directions) of Swing Arm 15 on the one hand, the longitudinal oscillation (Fig. 1 is perpendicular to the swing in paper direction) of Swing Arm 16 can be ensured again on the other hand.

The present embodiment, the below of described main shaft 8 is fixedly connected with clump weight 1, described Swing Arm 15 is in extreme lower position (main shaft is positioned at 0 ° of position) perpendicular to the center of gravity of clump weight 1 described during horizontal surface, its counterweight is according to Swing Arm and parallel system, shaft coupling and Swing Arm rotating mechanism, shaft coupling end handgrip coupling mechanism and grabbing workpiece weight summation coupling, and clump weight weight is between 18kg-27kg; Once Swing Arm swings in the vertical, clump weight all can rotate with the rotation of main shaft, and then the center of gravity of clump weight is raised, under the Action of Gravity Field of clump weight, a torsion contrary with main axis direction can be applied to main shaft, and then reduce driving torque to reduce driving power, be 3/5 of conventional six-joint robot second axle moment of torsion, thus reduce cost and energy efficient.

In the present embodiment, described main shaft 8 is supported on described base plate 3 by the framed side wallboard 6 that be arranged in parallel and front wallboard 26, the bottom of described framed side wallboard 6 and front wallboard 26 is fixed on described base plate 3, bearing 24 for supporting described main shaft 8 is separately fixed at described framed side wallboard 6 and front wallboard 26, described clump weight 1 is arranged between described framed side wallboard 6 and front wallboard 26, and then ensures the stability that main shaft 8 works.

In the present embodiment, described longitudinal driving rotation mechanism comprises the inlet/outlet mechanism actuating device 9 be arranged on above described main shaft 8, described inlet/outlet mechanism actuating device 9 is servomotor (also can be oil cylinder or cylinder), described servomotor is fixed on inlet/outlet mechanism motor cabinet 10, the end that ejects of described inlet/outlet mechanism actuating device 9 links with inlet/outlet mechanism connecting rod support 12, described inlet/outlet mechanism connecting rod support 12 is slidably arranged on the linear module 11 of inlet/outlet mechanism, described inlet/outlet mechanism connecting rod support 12 is hinged with inlet/outlet mechanism connecting rod 13, the other end of described inlet/outlet mechanism connecting rod 13 is hinged on described Swing Arm 15 by Swing Arm bearing 14, the hinge-point in the vertical direction of described inlet/outlet mechanism connecting rod 13 and described Swing Arm 15 is higher than the hinge-point of described inlet/outlet mechanism connecting rod support 12 with described inlet/outlet mechanism connecting rod, and then ensure that inlet/outlet mechanism connecting rod 13 can effectively promote Swing Arm 15.

In the present embodiment, linear module is reciprocating travel 230mm under the driving of servomotor, and the longitudinal oscillation angle of Swing Arm is 42 degree (dotted portions see on the left of Fig. 1); Main shaft drives Swing Arm is 65 degree (dotted portions see Fig. 2 left and right sides) at the pendulum angle of longitudinal direction.

In the present embodiment, the linear module 11 of described inlet/outlet mechanism is linear guides, and described inlet/outlet mechanism connecting rod support 12 is arranged in the rail groove of described linear guides.

In the present embodiment, described complete machine lifting assembly comprises the lifting motor 32 fixed on the ground, the mouth of described lifting motor 32 is coaxially connected with and drives screw mandrel 34, the axes normal of described driving screw mandrel 34 is arranged in horizontal surface, described driving screw mandrel 34 is provided with the commutator 31 with the screw thread fit on described driving screw mandrel 34, described commutator 31 is connected with the elevating screw 29 that horizontal direction extends, described commutator 31 is suitable for described driving screw mandrel 34 and turns described elevating screw 29 and rotate, also namely when lifting motor rotates, drive and drive screw mandrel rotating shaft, on the one hand commutator is moved up or down when described driving screw mandrel rotates, elevating screw 29 is then driven to rotate forward or backwards on the other hand, the thread rotary orientation of the axial midpoint both sides of described elevating screw 29 is contrary, the screw thread that two of described elevating screw 29 are reverse is arranged with the drive block 35 with the screw thread fit of corresponding rotation direction respectively, the upper and lower side of described drive block 35 is hinged with lifting bar 36 respectively, be positioned at the lower surface of upper end thereof at described base plate 3 of two described lifting bars 36 above described elevating screw 29, the lower end being positioned at two described lifting bars 36 below described elevating screw 29 is hinged on the upper surface of described rotary disk 28, and four described lifting bars are arranged in " X " shape, when described elevating screw 29 rotates forward, drive two described drive blocks 35 mutually away from, when described elevating screw 29 rotates backward, drive two described drive blocks 35 close to each other, as can be known from Fig. 1, when two described drive blocks 36 are close to each other, the whole height of robot is in decline state, when two drive blocks 36 mutually away from time, then the whole height of robot is in propradation, and height of its lifting is determined according to concrete operating mode.

Above an embodiment of the present utility model has been described in detail, but described content is only the preferred embodiment that the utility model is created, and can not be considered to for limiting practical range of the present utility model.All any equivalent variations done according to the utility model application range, all should still be within patent covering scope of the present utility model.

Claims (10)

1. based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: comprise rotary disk, the axes normal of described rotary disk is in horizontal surface, and the side of described rotary disk is provided with the rotary disk motor for driving described rotary disk circumference to rotate, the top of described rotary disk is provided with for the complete machine lifting assembly driving the sucker gripper of described robot vertically to rise or to decline, the top of described complete machine lifting assembly is fixedly installed the base plate of level, one end of described base plate is provided with the carriage assembly for supporting described sucker gripper, described carriage assembly is hinged with Swing Arm and the control stalk for assisting described Swing Arm to swing, the longitudinal hinge-point longitudinal oscillation of described Swing Arm under the driving of longitudinal drive rotating device bottom it, described Swing Arm is laterally hinged with a teeter under the driving of horizontal drive rotating device bottom it, described Swing Arm and described control stalk all upwards extend and be arranged in parallel, the upper end thereof of described Swing Arm has sucker pole pedestal, described sucker pole pedestal is horizontally disposed with, one end away from described Swing Arm of described sucker pole pedestal connects described sucker gripper, described sucker pole pedestal is hinged on the upper end of described Swing Arm by large bar connector alive, the rotation direction that described sucker pole pedestal is lived in connector at described large bar is vertical with the rotation direction of the relative described Swing Arm of described large bar connector alive, described control stalk is provided with two, two described control stalks overlap in the projection of main apparent direction, the both sides of described Swing Arm are laid respectively in the projection in side-looking direction, described control stalk all forms the articulated linkage structure of parallelogram in main apparent direction and side-looking direction with described Swing Arm, one end away from described sucker gripper of described sucker pole pedestal is fixedly connected on the connecting rod between two described control stalk upper ends.

2. as claimed in claim 1 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: the upper end of two described control stalks is all hinged with little bar connector alive, the axle center place of described little bar connector alive rotates and is provided with shaft coupling, described shaft coupling extends to described Swing Arm side and parallel with described sucker pole pedestal, connected by three axle connecting rods between the free end of two described shaft couplings, described sucker pole pedestal, described shaft coupling are all fixedly connected with described three axle connecting rods.

3., as claimed in claim 2 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: in side-looking direction, two described control stalks are symmetricly set on the both sides of described Swing Arm.

4. as claimed in claim 1 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: described horizontal drive rotating device comprises the mair motor be fixed on described base plate, the mouth of described mair motor is connected with retarder, the driving gear for Power output on described retarder engages with the driven gear be set on main shaft, described main shaft is rotatably arranged on described base plate by bearing, one end of described main shaft and the bottom-hinged of described Swing Arm, the articulated structure of described main shaft and described Swing Arm promotes described Swing Arm transverse reciprocating and swings when being suitable for described main axis, and be suitable for described longitudinal drive rotating device and drive described Swing Arm at longitudinal reciprocally swinging.

5., as claimed in claim 4 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: the below of described main shaft is fixedly connected with clump weight, described Swing Arm is in extreme lower position perpendicular to the center of gravity of clump weight described during horizontal surface.

6. as claimed in claim 5 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: described main shaft is supported on described base plate by the framed side wallboard that be arranged in parallel and front wallboard, the bottom of described framed side wallboard and described front wallboard is fixed on described base plate, described bearing for supporting described main shaft is separately fixed at described framed side wallboard and described front wallboard, and described clump weight is arranged between described framed side wallboard and described front wallboard.

7. the two-way transfer robot of two bars based on parallel principle as described in as arbitrary in claim 1-6, it is characterized in that: described longitudinal driving rotation mechanism comprises the inlet/outlet mechanism actuating device be arranged on above described main shaft, the end that ejects of described inlet/outlet mechanism actuating device links with inlet/outlet mechanism connecting rod support, described inlet/outlet mechanism connecting rod support is slidably arranged on the linear module of inlet/outlet mechanism, described inlet/outlet mechanism connecting rod support is hinged with inlet/outlet mechanism connecting rod, the other end of described inlet/outlet mechanism connecting rod is hinged on described Swing Arm, the hinge-point in the vertical direction of described inlet/outlet mechanism connecting rod and described Swing Arm is higher than the hinge-point of described inlet/outlet mechanism connecting rod support and described inlet/outlet mechanism connecting rod.

8., as claimed in claim 7 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: the linear module of described inlet/outlet mechanism is linear guides, described inlet/outlet mechanism connecting rod support is arranged in the rail groove of described linear guides.

9. as claimed in claim 8 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: described complete machine lifting assembly comprises the lifting motor fixed on the ground, the mouth of described lifting motor is coaxially connected with driving screw mandrel, the axes normal of described driving screw mandrel is arranged in horizontal surface, described driving screw mandrel is provided with the commutator with the screw thread fit on described driving screw mandrel, described commutator is connected with the elevating screw that horizontal direction extends, described commutator is suitable for described driving screw mandrel and turns the rotation of described elevating screw; The thread rotary orientation of the axial midpoint both sides of described elevating screw is contrary, the screw thread that two of described elevating screw are reverse is arranged with the drive block with the screw thread fit of corresponding rotation direction respectively, the upper and lower side of described drive block is hinged with lifting bar respectively, be positioned at the lower surface of upper end thereof at described base plate of two described lifting bars above described elevating screw, the lower end being positioned at two described lifting bars below described elevating screw is hinged on the upper surface of described rotary disk, and four described lifting bars are arranged in " X " shape; When described elevating screw rotates forward, drive two described drive blocks mutually away from, when described elevating screw rotates backward, drive two described drive blocks close to each other.

10. as claimed in claim 1 based on the two-way transfer robot of two bars of parallel principle, it is characterized in that: the lower end of described control stalk is hinged on described carriage assembly, the hinge-point of described control stalk lower end and the hinge-point of described Swing Arm lower end are positioned on same level line.