TW202140358A - Composite conveying and stacking device in which material bag are not pierced during a conveying process to avoid waste - Google Patents

Abstract

The present invention is a composite conveying and stacking device, comprising: a base and two clamping mechanisms, wherein the base has two guide rods, a two-way screw rod, and a driving unit; the driving unit is used to drive the two-way screw rod to rotate; the two clamping mechanisms are symmetrically arranged on the left and right sides of the base, which are driven by the two-way screw rod to be relatively close to or away from each other, and the two clamping mechanisms are respectively provided with a first telescopic cylinder, two second telescopic cylinders, a third telescopic cylinder, a shaft, a pivot seat, and a clamping jaw set; the lower end of the first telescopic cylinder is assembled with a pressing part, the two second telescopic cylinders and the shaft are pivotally connected to the pivot seat; the two second telescopic cylinders drive the pivot seat to pivotally rotate, the third telescopic cylinder is pivotally connected to the clamping jaw set, and the third telescopic cylinder drives the clamping jaw set to pivotally rotate; thereby ensuring the conveying operation to proceed smoothly, and preventing material bags from being pierced during the conveying process to avoid waste.

Description

Compound transport stacking device

The present invention relates to a conveying and stacking device, in particular to a composite conveying and stacking device for material bags.

According to, the materials (such as tea, wheat, white rice, beans, etc.) need to be bagged and packed into material bags after the production is completed, and then transported to the stacking device to be stacked on the pallet. In the early stage, the material bags are stacked on the pallet by manual handling Realize, labor intensity is high, work efficiency is low, labor cost is high, and there are safety hazards in the handling process.

To this end, some companies have developed such as the Chinese Utility Model Patent Announcement No. CN 209600912U "Feed Packing and Stacking Device", which includes a material-shaking conveying unit, a temporary storage unit arranged on one side of the material-shaking conveying unit, and a device arranged above the material-shaking conveying unit. An installation platform and a palletizing manipulator set on the installation platform. The end of the palletizing manipulator is provided with a clamping jaw unit. The clamping jaw unit includes a clamping jaw driving device and two clamping jaws arranged at the two output ends of the clamping jaw driving device. A number of L-shaped grippers are arranged on the upper space. The grippers on the two grippers are arranged oppositely and staggered. The gripper drive device is used to drive the two grippers to move closer or away from each other, so that the two grippers are closed or opened. , To automatically grab material bags and realize the stacking of material bags.

However, the above-mentioned previous proposal can only be driven by the gripper drive device to close the two grippers to grab the material bag or open to release the material bag. It is impossible to automatically adjust the distance between the two grippers and the length of the gripper according to the size of the material bag. It is very easy to puncture the material bag, which affects the handling operation and causes waste.

In view of the shortcomings of the above-mentioned previous proposals, the inventor of the present invention is based on the idea of thinking and creation, after many discussions, trial sample tests, and many modifications and improvements, and then came up with the present invention.

The present invention provides a composite transport stacking device, which includes a base, a set of connecting parts is arranged on the upper side, a platform is arranged on the lower side, two guide rods are arranged on the front and rear sides of the bottom of the platform, and a two-way screw is arranged in the middle of the bottom of the platform. The two-way screw is provided with two threaded sections with opposite spiral directions, and the platform is provided with a driving unit for driving the two-way screw to rotate; and two clamping mechanisms, which are symmetrically arranged on the left and right sides of the base , The two clamping mechanisms are respectively provided with a displacement plate, the middle part of the top surface of the displacement plate is provided with a screw seat and a first telescopic cylinder. Rotation drives the two clamping mechanisms to move closer or farther away. The first telescopic cylinder is provided with a first telescopic rod. The first telescopic rod passes downward through the displacement plate and is provided with a pressing portion, which can be used by the first telescopic cylinder. Drive the pressing part to move up and down, the displacement plate is provided with two second telescopic cylinders on the front and rear sides, the two second telescopic cylinders are respectively provided with a second telescopic rod, and the top surface of the displacement plate is on the two second telescopic cylinders and the two second telescopic cylinders. Two guide seats are provided between the screw seats, and the two guide rods of the base are provided with two guide seats. The cylinder is pivotally connected to a pivoting seat, the front and rear sides of the pivoting seat are provided with two pivoting arms. The connecting portion is pivotally connected to the ends of the second telescopic rods of the two second telescopic cylinders, and the shaft holes of the two pivoting arms are pivotally connected to both ends of the shaft rod, so that the pivot seat is pivoted on the displacement plate away from the base The pivot seat can be driven by the two second telescopic cylinders to pivot. The pivot seat is equidistantly provided with a plurality of downwardly extending arms, and the lower end of each arm is respectively combined with an outer tube. A clamping jaw group is pivoted on the side of the swivel away from the base. The clamping jaw group is equidistantly provided with plural swing arms. The lower ends of the plural swing arms are respectively pivoted to a clamping rod through a linkage rod. Located in the outer tube at the lower end of each arm, a third telescopic cylinder is provided in the middle of the top surface of the pivot seat, the third telescopic cylinder is provided with a third telescopic rod, the end of the third telescopic rod and the clamping jaw set It is pivotally connected, and the third telescopic cylinder can drive the clamping jaw set to pivot, and at the same time drive the clamping rods to slide and expand in each outer tube.

The main purpose of the composite handling and stacking device of the present invention is that it can automatically adjust the distance between the two clamping mechanisms and the position of the clamping jaw group according to the size of the material bag to be conveyed during use, so as to prevent the material bag from being pierced during the handling operation. , And can carry out the handling operation smoothly, avoiding waste.

The following further descriptions are provided in conjunction with the drawings of the preferred embodiments of the present invention, in order to enable those familiar with the related art of the present invention to implement them based on the statements in this specification.

First of all, please refer to the first to fourth figures. The present invention is a composite transport and stacking device. The composite transport and stacking device 1 includes a base 10 and two clamping mechanisms 20.

The base 10 is provided with a set of connecting portions 11 on the upper side, and a platform 12 at the lower end. The platform 12 is provided with two guide rods 13 on the front and rear sides of the bottom. Two threaded sections 141 in opposite directions are provided with a driving unit 15 on the platform 12, the driving unit 15 is used to drive the bidirectional screw 14 to rotate, and a limit baffle 131 is respectively set between the two ends of the two guide rods 13 .

The two clamping mechanisms 20 are symmetrically arranged on the left and right sides of the base 10. The two clamping mechanisms 20 are respectively provided with a displacement plate 21, and the middle part of the top surface of the displacement plate 21 is provided with a screw seat 22 and a first telescopic Cylinder 23. The screw seat 22 allows the threaded section 141 of the two-way screw 14 to pass through. The two-way screw 14 can rotate the two clamping mechanisms 20 to move closer or farther away. The first telescopic cylinder 23 is provided with a first The telescopic rod 231 (please refer to the eleventh figure for cooperation), the first telescopic rod 231 penetrates the displacement plate 21 downward to form a pressing portion 232, and the pressing portion 232 can be driven up and down by the first telescopic cylinder 23 The displacement plate 21 is provided with two second telescopic cylinders 24 on the front and rear sides. The two second telescopic cylinders 24 are respectively provided with a second telescopic rod 241. The top surface of the displacement plate 21 is on the two second telescopic cylinders 24 and the Two guide seats 25 are provided between the screw seats 22, and the two guide rods 13 of the base 10 are slid through the two guide seats 25. The displacement plate 21 is provided with a shaft 26 on the side away from the base 10. The shaft 26 and the two second telescopic cylinders 24 are pivotally connected to a pivot seat 27. The pivot seat 27 is provided with two pivot arms 271 at the front and rear sides. The ends of the two pivot arms 271 are respectively provided with a pivot portion 2711 , The middle part is respectively provided with a shaft hole 2712, the pivotal portion 2711 of the two pivoting arms 271 is pivotally connected to the ends of the second telescopic rods 241 of the two second telescopic cylinders 24, and the shaft holes 2712 of the two pivoting arms 271 and The two ends of the shaft 26 are pivotally connected, so that the pivot seat 27 is pivoted on the side of the displacement plate 21 away from the base 10, and the pivot seat 27 can be driven outward or inward by the two second telescopic cylinders 24 Pivoting, the pivot seat 27 is equidistantly provided with a plurality of downwardly extending support arms 272, the lower ends of each of the support arms 272 are respectively combined with an outer tube 2721, the pivot seat 27 is pivoted on the side away from the base with a clamp Claw set 28. The clamping jaw set 28 is equidistantly provided with a plurality of swing arms 281. The lower end of the plurality of swing arms 281 is pivotally connected to a clamping rod 283 through a linkage rod 282, and each clamping rod 283 penetrates each of the supporting arms. In the outer tube 2721 at the lower end of the 272, a third telescopic cylinder 29 is provided in the center of the top surface of the pivot seat 27. The third telescopic cylinder 29 is provided with a third telescopic rod 291. The group 28 is pivotally connected, and the third telescopic cylinder 29 can drive the clamping jaw group 28 to pivot outward or inward, and at the same time drive each of the clamping rods 283 to slide and expand in each of the outer tubes 2721.

The first telescopic cylinder 23, the second telescopic cylinder 24, and the third telescopic cylinder 29 may be pneumatic cylinders or hydraulic cylinders, respectively.

When in use, as shown in the fifth figure, the composite transporting and stacking device 1 is installed on a robotic arm 2 for clamping and picking up a material bag 4 conveyed on a conveyor belt 3 and transporting the material bag 4 to a stack Stacked on the board 5, the material contained in the material bag 4 can be tea, wheat, white rice, beans, etc.

When transporting and stacking, as shown in Figure 6, the composite transporting and stacking device 1 is relatively far away from the two clamping mechanisms 20, and the pivot seat 27 and the clamping jaw set 28 of the two clamping mechanisms 20 are pivoted outwards. The robotic arm 2 drives the displacement to the top of the material bag 4, as shown in the seventh figure, the robotic arm 2 drives the composite handling and stacking device 1 to move down, so that the material bag 4 is located between the two clamping mechanisms 20, as shown in the eighth figure As shown, the third telescopic rod 291 of the third telescopic cylinder 29 of the two clamping mechanisms 20 is extended to drive the clamping jaw set 28 to pivot inward, and then drive the clamping rods 283 of the clamping jaw set 28 toward the base 10 in the outer tube 2721. As shown in the ninth figure, the second telescopic rods 241 of the two second telescopic cylinders 24 of the two clamping mechanisms 20 extend and drive the pivot seat 27 to pivot inward, so that the clamping rod 283 is against the material At the bottom of the bag 4, as shown in the tenth figure, the drive unit 15 drives the bidirectional screw 14 to rotate in the reverse direction. The rotation of the bidirectional screw 14 drives the two clamping mechanisms 20 to approach relatively, so that the clamping rods 283 of the two clamping mechanisms 20 abut against each other. Supported at the bottom of the material bag 4, as shown in the eleventh figure, the first telescopic rod 231 of the first telescopic cylinder 23 of the two clamping mechanisms 20 extends to drive the pressing part 232 to descend and move, so that the pressing part 232 is pressed against the material On the bag 4, the material bag 4 can be firmly clamped. As shown in the twelfth figure, the robot arm 2 drives the composite handling and stacking device 1 to move upward, and the material bag 4 is clamped to a proper height, as shown in the thirteenth figure. As shown, the mechanical arm 2 is rotated to move the material bag 4 to the top of the pallet 5. As shown in the fourteenth figure, the first telescopic rod 231 of the first telescopic cylinder 23 of the two clamping mechanisms 20 is shortened to drive the pressing part 232 Ascending displacement, the drive unit 15 drives the two-way screw 14 to rotate, and the two-way screw 14 rotates to drive the two clamping mechanisms 20 to move away from each other. The second telescopic rods 241 of the two second telescopic cylinders 24 of the two clamping mechanisms 20 shorten and drive the pivot seat 27 Pivoting outwards, the third telescopic rod 291 of the third telescopic cylinder 29 is shortened to drive the gripper set 28 to pivot outward, release the material bag 4, stack the material bag 4 on the pallet 5, and then be driven by the robotic arm 2 The composite handling and stacking device 1 is moved to the top of the material bag 4 again, and operates in this way,

From the structure of the above specific embodiment, the following benefits can be obtained:

The composite transporting and stacking device of the present invention can automatically adjust the distance between the two clamping mechanisms 20 and the position of the clamping jaw set 28 according to the size of the material bag 4 to be transported during use, so as to ensure the clamping jaw set 28 of the two clamping mechanisms 20 The clamping rod 283 relatively abuts against the bottom of the material bag 4, and the pressing portion 232 of the first telescopic cylinder 23 of the two clamping mechanisms 20 is pressed against the material bag 4 to firmly clamp the material bag 4 for handling operations The material bag 4 will not be pierced from time to time, and the handling operation can be carried out smoothly, avoiding waste.

1: Compound handling stacking device 2: Robotic arm 3: Roller belt 4: Material bag 5: Pallet 10: Pedestal 11: Assembly Department 12: Platform 13: guide rod 131: limit baffle 14: Two-way screw 141: thread section 15: drive unit 20: Clamping mechanism 21: Displacement plate 22: Screw seat 23: The first telescopic cylinder 231: The first telescopic pole 232: Pressure Department 24: The second telescopic cylinder 241: Second telescopic pole 25: guide seat 26: Axle 27: pivot seat 271: Pivoting Arm 2711: Pivot 2712: Shaft hole 272: support arm 2721: Outer tube 28: Gripper group 281: Swing Arm 282: Link Rod 283: Clamp Rod 29: The third telescopic cylinder 291: third telescopic rod

The first figure is a perspective view of the appearance of the present invention. The second figure is a three-dimensional exploded view of the present invention. The third figure is a three-dimensional exploded view of the clamping mechanism of the present invention. The fourth figure is an exploded perspective view of another clamping mechanism of the present invention. The fifth figure is a perspective view of the present invention in use. The sixth figure is the first schematic diagram of the operation of the present invention. The seventh figure is the second schematic diagram of the operation of the present invention. The eighth figure is the third schematic diagram of the operation of the present invention. The ninth figure is the fourth schematic diagram of the operation of the present invention. The tenth figure is the fifth schematic diagram of the operation of the present invention. The eleventh figure is the sixth schematic diagram of the use action of the present invention. Figure 12 is the seventh schematic diagram of the operation of the present invention. Figure 13 is the eighth schematic diagram of the operation of the present invention. Figure 14 is the ninth schematic diagram of the operation of the present invention.

1: Compound handling stacking device

10: Pedestal

11: Assembly Department

12: Platform

13: guide rod

131: limit baffle

14: Two-way screw

141: thread section

15: drive unit

20: Clamping mechanism

21: Displacement plate

22: Screw seat

23: The first telescopic cylinder

24: The second telescopic cylinder

25: guide seat

26: Axle

27: pivot seat

271: Pivoting Arm

272: support arm

2721: Outer tube

28: Gripper group

281: Swing Arm

282: Link Rod

283: Clamp Rod

29: The third telescopic cylinder

Claims (5)

A composite transport stacking device, including: A base with a set of connecting parts on the upper side and a platform on the lower side. The bottom of the platform is provided with two guide rods on the front and rear sides. A two-way screw is provided in the middle of the bottom of the platform. The two-way screw is provided with two threaded sections with opposite spiral directions. , In addition, a driving unit is provided on the platform, and the driving unit is used to drive the two-way screw to rotate; and Two clamping mechanisms are arranged symmetrically on the left and right sides of the base. The two clamping mechanisms are respectively provided with a displacement plate. The middle part of the top surface of the displacement plate is provided with a screw seat and a first telescopic cylinder. The threaded section of the two-way screw is threaded, and the two gripping mechanisms can be driven by the two-way screw to move closer or farther away. The first telescopic cylinder is provided with a first telescopic rod, and the first telescopic rod passes downward through the The displacement plate is assembled with a pressing part, and the pressing part can be driven by the first telescopic cylinder to move up and down. The front and rear sides of the displacement plate are provided with two second telescopic cylinders, and the two second telescopic cylinders are respectively provided with a second telescopic cylinder. The top surface of the displacement plate is provided with two guide seats between the two second telescopic cylinders and the screw seat. The two guide seats allow the two guide rods of the base to pass through and slide. A shaft is provided on one side, and a pivot seat is pivotally connected by using the shaft and the two second telescopic cylinders. The front and rear sides of the pivot seat are provided with two pivot arms, and the ends of the two pivot arms are respectively provided with a pivot part , The middle part is respectively provided with a shaft hole, the pivotal part of the two pivoting arms is pivotally connected to the end of the second telescopic rod of the two second telescopic cylinders, and the shaft holes of the two pivoting arms are pivotally connected to both ends of the shaft rod , The pivot seat is pivoted on the side of the displacement plate away from the base, and the pivot seat can be driven to pivot by the two second telescopic cylinders, and the pivot seat is pivoted on the side away from the base A clamping jaw set, a third telescopic cylinder is arranged in the middle of the pivot seat, and a third telescopic rod is arranged on the third telescopic cylinder. The cylinder drives the clamping jaw group to pivot. The composite transporting and stacking device according to claim 1, wherein the pivot seat is equidistantly provided with a plurality of downwardly extending support arms, the lower ends of each of the support arms are respectively combined with an outer tube, and the clamping jaw group is equidistantly provided with a plurality of Swing arms, the lower ends of the plurality of swing arms are respectively pivotally connected to a clamping rod, and each clamping rod is respectively penetrated in the outer tube at the lower end of each support arm, and can be driven by the third telescopic cylinder to pivot the clamping jaw group, Drive each of the clamping rods to slide and expand in each of the outer tubes. The composite transport stack device according to claim 2, wherein the lower ends of the swing arms of the clamping jaw set are respectively pivotally connected to the clamping rods through a linkage rod. According to claim 1, the composite transporting and stacking device, wherein a limit baffle is respectively arranged between the two ends of the two guide rods of the base. The composite transport stack device according to claim 1, wherein the first telescopic cylinder, the second telescopic cylinder, and the third telescopic cylinder are pneumatic cylinders or hydraulic cylinders.

Images