CN220196172U - Multifunctional buffer mechanism suitable for punching automatic line - Google Patents

Abstract

The utility model provides a multi-functional buffer memory mechanism suitable for die-cut automation line, includes buffer memory platform, platform support curb plate, mobile device, photoelectric sensor and platform support, and the platform support curb plate is provided with two, fixes respectively in the left and right sides of platform support top, and buffer memory platform left and right sides is passed through the screw fixation respectively on "L" type connecting plate, "L" type connecting plate is connected with mobile device, and mobile device includes slide rail, slider and pen-shaped cylinder, and the slide rail is fixed on the medial surface of platform support curb plate, slider one end is fixed on "L" type connecting plate lateral wall, and the other end and sliding rail connection, pen-shaped cylinder pass through the connecting seat to be fixed in platform support curb plate inside wall one end, and the telescopic link tip and the outer wall connection of "L" type connecting plate of pen-shaped cylinder, photoelectric sensor are fixed on two platform support curb plate lateral walls. The utility model can realize the movement transformation of the multi-layer platform and is suitable for the common use of parts with different section shapes and shapes.

Description

Multifunctional buffer mechanism suitable for punching automatic line

Technical Field

The utility model relates to a part caching mechanism, in particular to a multifunctional caching mechanism suitable for punching an automatic line.

Background

In recent years, the technology of an automatic production line has been widely used, and various processes on the production line have been greatly developed. However, the part buffering mechanism arranged on the production line for resisting unexpected risks is limited by product interception and shape, and particularly, the buffering mechanism is required to be arranged on the multi-variety part integration line for each product. The existing buffer mechanism is a buffer platform fixed on a fixing frame, parts with corresponding sizes can only be placed on one buffer mechanism, the buffer platform cannot be moved and replaced, the parts are difficult to take and place, and the special mechanism is wasteful in production field and increases production beats, so that the production cost is increased. In view of the above, it is necessary to design a mechanism that can meet the requirements of different products for storage, flexible movement, and quick response, and is suitable for common use of parts of different shapes and shapes.

Disclosure of Invention

The utility model provides a multifunctional buffer mechanism suitable for punching an automation line, which can realize the movement transformation of a multi-layer platform and is suitable for the common use of parts with different section types and shapes.

The technical scheme adopted for solving the technical problems is as follows:

the utility model provides a multi-functional buffer memory mechanism suitable for die-cut automation line, buffer memory mechanism includes buffer memory platform, platform support curb plate, mobile device, photoelectric sensor and platform support, the platform support curb plate is provided with two, fixes respectively the left and right sides at platform support top, buffer memory platform left and right sides is fixed on "L" type connecting plate through the screw respectively, "L" type connecting plate with mobile device connects, mobile device includes slide rail, slider and pen-shaped cylinder, the slide rail is fixed on the medial surface of platform support curb plate, slider one end is fixed on "L" type connecting plate lateral wall, the other end with slide rail connection, pen-shaped cylinder passes through the connecting seat to be fixed platform support curb plate inside wall one end, pen-shaped cylinder's telescopic link tip with the outer wall connection of "L" type connecting plate, photoelectric sensor fixes two on the platform support curb plate lateral wall.

Above-mentioned multi-functional buffer gear suitable for die-cut automation line, the buffer memory platform is provided with a plurality of layers, every layer buffer memory platform's left and right sides all is connected with a set of slide rail and slider, one of them side of buffer memory platform with pen-shaped cylinder is connected, the interval is provided with a plurality of part positioner on buffer memory platform's the mesa, every part positioner includes guide block and locating pin, the guide block is provided with two, and control the interval is fixed buffer memory platform front end, the locating pin sets up buffer memory platform rear end, and be located two between the guide block.

Above-mentioned multi-functional buffer gear suitable for die-cut automation line, part positioner still includes the location base, the location base is fixed on the mesa of buffer platform, two the guide block interval sets up on the location base, the locating pin sets up two on the location base between the guide block.

Above-mentioned multi-functional buffer gear suitable for die-cut automation line, buffer gear still is provided with the buffer, every layer be provided with two on the plane that the buffer platform is located the buffer is fixed at same platform support curb plate front and back end respectively through the hornblock, every still be provided with hard spacing on the hornblock, hard spacing is hexagon bolt.

Above-mentioned multi-functional buffer gear suitable for die-cut automation line, with every layer every of buffer platform junction all be provided with two on the outer wall of platform support curb plate the interval around all photoelectric sensor.

The beneficial effects of the utility model are as follows: the part caching mechanism is simultaneously provided with the multi-layer caching platforms, the multi-layer caching platforms can be provided with the positioning devices according to the types of the parts, each layer of caching platform is fixed on the L-shaped connecting plate through the screws, and the part caching mechanism is convenient to replace and suitable for common use of the parts with different section types and hole sites; in addition, each layer of buffer platform can be independently moved, and the operation of the buffer platform is controlled according to photoelectric sensor signals, so that the process of picking and placing parts by an automatic line truss manipulator is realized. The buffer mechanism of the utility model improves the unexpected risk resistance capability of the automatic production line, reduces the production cost and improves the time utilization rate.

Drawings

The utility model is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of a buffer mechanism according to the present utility model;

FIG. 2 is a schematic diagram of a buffer mechanism after a portion of the parts are placed;

fig. 3 is a schematic diagram of a mobile device.

In the figure: 1. a cache platform; 2. a platform supporting side plate; 3. a photoelectric sensor; 4. a platform bracket; 5. an L-shaped connecting plate; 6. a slide rail; 7. a slide block; 8. a pen-shaped cylinder; 9. a guide block; 10. a positioning pin; 11. positioning a base; 12. a buffer; 13. a part; 14. hard limit.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

Referring to fig. 1, the utility model relates to a multifunctional buffer mechanism suitable for punching an automation line, which is characterized in that: the caching mechanism comprises a caching platform 1, a platform supporting side plate 2, a moving device, a photoelectric sensor 3 and a platform bracket 4, wherein the two platform supporting side plates 2 are respectively fixed on the left side and the right side of the top of the platform bracket 4, and the left end and the right end of the caching platform 1 are respectively fixed on an L-shaped connecting plate 5 through screws, so that the types of the caching platform can be conveniently replaced according to the types of the parts; the L-shaped connecting plate 5 is connected with the moving device, the moving device comprises a sliding rail 6, a sliding block 7 and a pen-shaped air cylinder 8, the sliding rail 6 is fixed on the inner side surface of the platform supporting side plate 2, one end of the sliding block 7 is fixed on the outer side wall of the L-shaped connecting plate 5, the other end of the sliding block is connected with the sliding rail 6, the pen-shaped air cylinder 8 is fixed on one end of the inner side wall of the platform supporting side plate 2 through a connecting seat, the end part of a telescopic rod of the pen-shaped air cylinder 8 is connected with the outer wall of the L-shaped connecting plate 5, and the telescopic rod of the pen-shaped air cylinder is used for driving the front and back movement of a caching platform so as to facilitate the picking and placing of parts by a manipulator; the photoelectric sensor 3 is fixed on the outer side walls of the two platform supporting side plates 2.

The buffer platform 1 is provided with a plurality of layers, for example, in fig. 1, four layers are provided and are divided into two structures, two ends of the buffer platform 1 are respectively connected with a group of slide rails 6 and slide blocks 7, one side of the buffer platform 1 is connected with the pen-shaped air cylinder 8, a plurality of part positioning devices are arranged on the table top of the buffer platform 1 at intervals, four groups of part positioning devices are arranged on one layer of buffer platform at intervals in fig. 1, one part positioning device on the buffer platform comprises guide blocks 9 and positioning pins 10, the 2 nd layer to the 4 th layer from top to bottom in fig. 2 are seen, the guide blocks 9 of the same group are provided with two, the left and right intervals are fixed at the front end of the buffer platform 1, the positioning pins 10 are arranged at the rear end of the buffer platform 1 and are positioned between the two guide blocks 9, the parts 13 are directly placed between the two guide blocks, and the positioning pins are clamped into pin holes on the parts to position the parts.

The other part positioning device on the cache platform comprises positioning bases 11 except for guide blocks and positioning pins, the uppermost cache platform in fig. 2 is seen, a group of positioning devices are provided with two positioning bases, the front and back intervals are fixed on the table top of the cache platform 1, two guide blocks are arranged on each positioning base 11 at left and right intervals, and the positioning pins 10 are arranged on the positioning bases 11 between the two guide blocks 9 at the rear end.

Referring to fig. 1 and 3, two buffers 12 are disposed on the inner side walls of the platform supporting side plates 2, two buffers are disposed on the plane where the buffer platform 1 is disposed, the buffers are fixed at the front end and the rear end of the same platform supporting side plate through corner blocks respectively, a hard limit is further disposed on each corner block, the hard limit is a hexagonal bolt structure and is used for buffering and limiting each layer of buffer platform in front-back translation, the buffers disposed on the two platform supporting side plates corresponding to the two layers of buffer platforms adjacent to each other are disposed on the two platform supporting side plates in a left-right staggered mode, and the buffers of each layer are disposed on the same side as the pen-shaped cylinder. Two photoelectric sensors 3, for example, four layers of buffer platforms, are arranged on the outer wall of each platform supporting side plate 2 at intervals in front of and behind each platform at the joint of each buffer platform 1, 16 photoelectric sensors are arranged in total, and 8 photoelectric sensors are arranged on each platform supporting side plate. When the photoelectric sensor works, light is emitted, the light is emitted to contact the surface of the part, the light is reflected, the photoelectric sensor receives a light signal and converts the light signal into an electric signal to be sent out, the part is stored at the corresponding position, and if the reflected light is not received, the photoelectric sensor does not send out a signal, and the corresponding position is the part. The model of the photoelectric sensor is GTB6-P7211.

Referring to fig. 2, two part processes: when the cache platform device processes a part I: feeding the truss manipulator on an automation line to the uppermost layer of buffer platform position 1 and position 3 (part positioning device positions 1 to 4 from left to right in fig. 2), wherein a left photoelectric sensor detects signals; when the truss manipulator is charged next time, if the left photoelectric sensor still obtains signals, the part is placed to the position 2 and the position 4 of the uppermost layer of the buffer platform, the two photoelectric sensors detect signals, the part on the buffer platform is fully filled, and then the alarm is manually processed.

When the part II is processed: feeding the truss manipulator on an automation line to a position 1 and a position 3 of a buffer platform (from top to bottom) of a second layer, wherein a left photoelectric sensor detects signals; when the truss manipulator is fed next time, if the left photoelectric sensor still obtains signals, the part is placed to a position 2 and a position 4 of a second-layer caching platform, the two photoelectric sensors detect the signals, and then the whole caching platform is driven by a pen-shaped cylinder to return to the proper position; and feeding again, namely placing the material in the buffer platform position 1 and the buffer platform position 3 of the third layer, and repeating the steps. And if the left and right side photoelectric sensors cannot detect signals, the whole caching platform is driven by the pen-shaped air cylinder to extend to an initial position, and the caching platform is continuously discharged. If the photoelectric sensors at the two ends of the three cache platforms all obtain signals, indicating that the stock is full, alarming and manually processing.

Claims (5)

1. Multifunctional buffer mechanism suitable for die-cut automation line, its characterized in that: the utility model provides a buffer memory mechanism includes buffer memory platform (1), platform support curb plate (2), mobile device, photoelectric sensor (3) and platform support (4), platform support curb plate (2) are provided with two respectively fix platform support (4) top left and right sides, buffer memory platform (1) left and right sides is fixed on "L" type connecting plate (5) through the screw respectively, "L" type connecting plate (5) with mobile device connects, mobile device includes slide rail (6), slider (7) and pen-shaped cylinder (8), slide rail (6) are fixed on the medial surface of platform support curb plate (2), slider (7) one end is fixed on "L" type connecting plate (5) lateral wall, the other end with slide rail (6) are connected, pen-shaped cylinder (8) are fixed through the connecting seat platform support curb plate (2) inside wall one end, telescopic link tip of pen-shaped cylinder (8) with the outer wall connection of "L" type connecting plate (5), photoelectric sensor (3) are fixed on two lateral walls of support (2).

2. The multi-functional caching mechanism for die-cut automation line of claim 1, wherein: the utility model discloses a buffer memory platform, including buffer memory platform (1), guide block (9), locating pin (10), guide block (9) are provided with two, control the interval and fix buffer memory platform (1) front end, locating pin (10) set up buffer memory platform (1) rear end, and be located two on the mesa of buffer memory platform (1) a plurality of part positioner is provided with to buffer memory platform (1) interval on the mesa, every part positioner includes guide block (9) and locating pin (10), guide block (9) are provided with two, control the interval and fix buffer memory platform (1) front end, locating pin (10) set up buffer memory platform (1) rear end is located two between guide block (9).

3. The multi-functional caching mechanism for die-cut automation line of claim 2, wherein: the part positioning device further comprises a positioning base (11), the positioning base (11) is fixed on the table top of the cache platform (1), two guide blocks (9) are arranged on the positioning base (11) at intervals, and the positioning pin (10) is arranged on the positioning base (11) between the two guide blocks (9).

4. A multi-functional caching mechanism for die-cut automation line as defined in claim 3, wherein: the buffer mechanism is further provided with buffers (12), each layer of buffer platform (1) is provided with two buffers (12) on the plane, the buffers are fixed at the front end and the rear end of the same platform supporting side plate (2) through corner blocks respectively, each corner block is further provided with a hard limit (14), and the hard limit is a hexagon bolt.

5. The multi-functional caching mechanism for die-cut automation line of claim 4, wherein: two photoelectric sensors (3) are arranged on the outer wall of each platform supporting side plate (2) at intervals front and back at the joint of each layer of the buffer platform (1).