CN220936934U - Step-by-step transfer mechanism for sleeves of isolation clothes - Google Patents

Abstract

The utility model provides an isolation sleeve step-by-step transfer mechanism, includes the frame, two sleeve translation mechanisms are installed to parallel in the frame, sleeve translation mechanism includes from lower supreme adsorption plate, flexible actuating mechanism and the translation sliding mechanism that connects gradually, translation sliding mechanism drive adsorption plate horizontal reciprocating motion, and flexible actuating mechanism drive adsorption plate reciprocates from top to bottom, and the adsorption plate on two sleeve translation mechanisms moves in opposite directions or dorsad, and translation sliding mechanism is connected with the frame installation. The adsorption plate is used for adsorbing the cut sleeves, the telescopic actuating mechanism can lift the adsorption plate, and the translation sliding mechanism drives the adsorption plate to move outwards. By arranging two sleeve translation mechanisms to run opposite directions or back to back, two sleeve cloths on one cloth can be taken out and synchronously moved to two sides of the clothing body.

Description

Step-by-step transfer mechanism for sleeves of isolation clothes

Technical Field

The utility model relates to the technical field of production of isolation clothes, in particular to a stepping transfer mechanism for sleeves of isolation clothes.

Background

In the production of medical isolation clothes, the sleeves of the existing isolation clothes are sewn by hand, so that the production efficiency is low. At present, there is also an arrangement for welding the sleeves of the isolation, for example, chinese patent document CN116690995A discloses an apparatus for welding the sleeves of the isolation, which welds the cloth of the sleeves to the cloth of the body from both sides, and then cuts the cloth, because the cloth of the sleeves has an irregular trapezoid structure, the cloth waste is large. In order to solve the problem, the sleeves are cut on one cloth and welded on the clothing body, and in the process, two sleeves on one cloth are taken out and moved to two sides of the clothing body, so that a stepping transfer mechanism for sleeve transfer is designed.

Disclosure of utility model

The utility model aims to solve the technical problems that: the problem existing in the background technology is solved, and the stepping transfer mechanism for the sleeves is provided, and two sleeve cloths on one cloth are taken out and moved to two sides of a clothing body by arranging two sleeve translation mechanisms to run oppositely or back to back.

In order to achieve the technical characteristics, the aim of the utility model is realized in the following way: the utility model provides an isolation sleeve step-by-step transfer mechanism, includes the frame, two sleeve translation mechanisms are installed to parallel in the frame, sleeve translation mechanism includes from supreme adsorption plate, flexible actuating mechanism and the translation sliding mechanism that connects gradually down, translation sliding mechanism drive adsorption plate horizontal reciprocating motion, and flexible actuating mechanism drive adsorption plate reciprocates from top to bottom, and the adsorption plate on two sleeve translation mechanisms moves in opposite directions or dorsad, and translation sliding mechanism is connected with the frame installation.

The adsorption plate is a hollow plate body, a plurality of adsorption holes are formed in the lower side of the hollow plate body, and a suction interface is formed in the upper side of the hollow plate body.

The upside of adsorption plate is equipped with the reinforcing frame, and the suction interface sets up on the reinforcing frame, reinforcing frame and adsorption plate's inside intercommunication.

The upper side of the adsorption plate is provided with a plurality of telescopic actuating mechanisms, and a plurality of telescopic actuating mechanisms are connected with the translation sliding mechanism through a supporting structure.

The support structure comprises a first support plate, wherein second support plates are respectively arranged at two ends of the lower side of the first support plate, a plurality of telescopic actuating mechanisms are respectively arranged at the lower side of the second support plate, and the first support plate is connected with the translation sliding mechanism.

The translational sliding mechanisms are provided with two sets, a third supporting plate is further installed on the upper side of the first supporting plate, and the third supporting plate is connected with the two sets of translational sliding mechanisms.

The translation sliding mechanism is a linear sliding module, the linear sliding module comprises a sliding rail assembly and a sliding block arranged on the sliding rail assembly, a driver is arranged on the sliding rail assembly and drives the sliding block to reciprocate, and the telescopic actuating mechanism is connected with the sliding block.

The translation sliding mechanism is a linear sliding module, the linear sliding module comprises a sliding rail assembly and a sliding block arranged on the sliding rail assembly, two sets of translation sliding mechanisms are connected and driven through a transmission shaft, a driver is arranged on one translation sliding mechanism, the sliding blocks on the two sets of translation sliding mechanisms are driven to synchronously operate by the driver, and a third supporting plate is connected with the sliding block.

The telescopic actuating mechanism is an air cylinder or an oil cylinder.

When the telescopic actuating mechanism is in a retracted state, the height of one adsorption plate is higher than that of the other adsorption plate, and when the telescopic actuating mechanism is in an extended state, the lower side surfaces of the two adsorption plates can be propped against the same plane.

The utility model has the following beneficial effects:

1. The adsorption plate is used for adsorbing the cut sleeves, the adsorption plate is used for adsorbing the sleeves, flatness of the sleeves in the moving process can be guaranteed, the adsorption plate can be lifted by the telescopic actuating mechanism, the adsorption plate is driven to move outwards by the translation sliding mechanism, and two sleeve translation mechanisms are arranged to run oppositely or back to back, so that two sleeve cloth on one cloth can be taken out and moved to two sides of a garment body.

2. The upper side of the adsorption plate is provided with a plurality of telescopic actuating mechanisms, so that the adsorption plate can be lifted stably. The translation sliding mechanism is provided with two sets, so that the stability in the translation process is ensured.

3. When the telescopic actuating mechanism is in a retracted state, the height of one adsorption plate is higher than that of the other adsorption plate, and in order to ensure that the adsorption plates can be adsorbed on the sleeves on the plane, the lower side surfaces of the two adsorption plates can be abutted against the same plane when the telescopic actuating mechanism is in an extended state. Under the condition of saving cloth, the two adsorption plates are ensured not to interfere in the process of outwards moving respectively.

Drawings

Fig. 1 is a schematic perspective view of the present utility model.

Fig. 2 is a schematic side view of the present utility model.

Fig. 3 is a schematic front view of the sleeve translation mechanism of the present utility model.

Fig. 4 is a schematic side view of the sleeve translation mechanism of the present utility model.

Fig. 5 is a perspective view of the sleeve translation mechanism of the present utility model.

Fig. 6 is a perspective view of another view of the sleeve translation mechanism of the present utility model.

In the figure: a frame 100, a support frame 110, an abutting plate 120 and a sleeve translation mechanism 200;

The suction device comprises a suction plate 1, a suction hole 11, a suction interface 12, a reinforcing frame 13, a connecting plate 14, a telescopic actuator 2, a translational sliding mechanism 3, a sliding rail assembly 31, a sliding block 32, a driver 33, a transmission shaft 34, a support structure 4, a second support plate 41, a first support plate 42 and a third support plate 43.

Detailed Description

Embodiments of the present utility model will be further described with reference to the accompanying drawings.

Referring to fig. 1-6, the step-by-step transfer mechanism for isolating sleeves comprises a frame 100, two sets of sleeve translation mechanisms 200 are parallelly arranged on the frame 100, each sleeve translation mechanism 200 comprises an adsorption plate 1, a telescopic actuating mechanism 2 and a translation sliding mechanism 3 which are sequentially connected from bottom to top, the translation sliding mechanism 3 drives the adsorption plate 1 to horizontally reciprocate, the telescopic actuating mechanism 2 drives the adsorption plate 1 to reciprocate up and down, the adsorption plates 1 on the two sets of sleeve translation mechanisms 200 are operated in opposite directions or back to back, and the translation sliding mechanism 3 is connected with the frame 100 in an installation manner. The adsorption plate 1 is used for adsorbing the cut sleeves, the telescopic actuating mechanism 2 can lift the adsorption plate 1, and the translation sliding mechanism 3 drives the adsorption plate 1 to move outwards. By providing two sleeve translation mechanisms 200 to run in opposite or back to back, two sleeve cloths on one cloth can be taken out and moved to both sides of the body.

The adsorption plate 1 is adopted to adsorb the sleeves, so that the smoothness of the sleeves in the moving process can be ensured. Specifically, referring to fig. 5 and 6, the adsorption plate 1 is a hollow plate body, a plurality of adsorption holes 11 are formed in the lower side of the hollow plate body, and a suction interface 12 is formed in the upper side of the hollow plate body. The adsorption holes 11 are used for adsorbing sleeves, and the suction interfaces 12 are used for being connected with negative pressure pipelines to provide negative pressure for the adsorption plate 1. Specifically, the adsorption plate 1 has a trapezoid structure with one wide end and one narrow end.

Referring to fig. 5, in order to secure flatness of the adsorption plate 1, the upper side of the adsorption plate 1 is provided with a reinforcing frame 13, and the suction port 12 is provided on the reinforcing frame 13, the reinforcing frame 13 communicating with the inside of the adsorption plate 1. When the reinforcing frame 13 is provided, the telescopic actuator 2 is not convenient to be connected with the adsorption plate 1, the connecting plate 14 can be arranged on the reinforcing frame 13, and the telescopic actuator 2 is connected with the connecting plate 14.

Referring to fig. 3 and 6, a plurality of telescopic actuators 2 are mounted on the upper side of the adsorption plate 1, and a plurality of telescopic actuators 2 are connected with a translational sliding mechanism 3 through a supporting structure 4. Through the structure, the adsorption plate 1 can be lifted stably.

Specifically, the support structure 4 includes a first support plate 42, two ends of a lower side of the first support plate 42 are respectively provided with a second support plate 41, a plurality of telescopic actuators 2 are respectively installed on a lower side of the second support plate 41, and the first support plate 42 is connected with the translational sliding mechanism 3. By means of the support structure 4, a plurality of telescopic actuators 2 are connected with the translational sliding mechanism 3.

Further, in order to ensure stability in the translation process, the translation sliding mechanism 3 is provided with two sets, a third supporting plate 43 is further installed on the upper side of the first supporting plate 42, and the third supporting plate 43 is connected with the two sets of translation sliding mechanisms 3.

When the top wall of the frame 100 has a mounting position, the two sets of translational sliding mechanisms 3 can be directly mounted and fixed with the frame 100, see fig. 2, when the frame adopts an industrial aluminum profile, a plurality of butt plates 120 can be mounted on the lower side of the industrial aluminum profile, and the two sets of translational sliding mechanisms 3 are mounted and connected with the butt plates 120.

The translational sliding mechanism 3 is a linear sliding module, the linear sliding module comprises a sliding rail assembly 31 and a sliding block 32 arranged on the sliding rail assembly 31, a driver 33 is arranged on the sliding rail assembly 31, the driver 33 drives the sliding block 32 to reciprocate, and when the translational sliding mechanism 3 is arranged, the telescopic actuating mechanism 2 is connected with the sliding block 32. The telescopic actuating mechanism 2 is driven to transversely reciprocate through the linear sliding module. The linear sliding module is a prior art, and the driver 33 may be in transmission connection with the slider 32 through a ball screw or a synchronous belt.

In another scheme, the translational sliding mechanisms 3 are provided with two sets, the translational sliding mechanisms 3 are linear sliding modules, each linear sliding module comprises a sliding rail assembly 31 and a sliding block 32 arranged on the sliding rail assembly 31, the two sets of translational sliding mechanisms 3 are connected and driven through a transmission shaft 34, a driver 33 is arranged on one translational sliding mechanism 3, the driver 33 drives the sliding blocks 32 on the two sets of translational sliding mechanisms 3 to synchronously operate, and a third supporting plate 43 is connected with the sliding blocks 32 on the two sets of translational sliding mechanisms 3. The telescopic actuating mechanism 2 is driven to transversely reciprocate through the linear sliding module. The linear sliding module is a prior art, and the driver 33 may be in transmission connection with the slider 32 through a ball screw or a synchronous belt. In addition, the connection transmission between the two sets of translation sliding mechanisms 3 is realized by installing a transmission shaft 34 between the two sets of existing linear sliding modules.

In a preferred embodiment, the telescopic actuator 2 is a cylinder or an oil cylinder. Of course, other mechanical structures with lifting functions, such as for example a SWL-like lift structure, may also be used.

Referring to fig. 1 and 2, since the sleeves are shaped like a trapezoid with different specifications, the adsorption plates 1 are also of a trapezoid structure with one wide end and one narrow end, and when the sleeves are cut on one piece of cloth, in order to save the cloth, the interval between the sleeves and the sleeves is small, in order to ensure that the two adsorption plates 1 do not interfere in the process of respectively moving outwards, when the telescopic actuator 2 is in a retracted state, the height of one adsorption plate 1 is higher than that of the other adsorption plate 1 on the two sets of sleeve translation mechanisms 200. In order to ensure that the two sleeves can be adsorbed on a plane, when the telescopic actuating mechanism 2 is in an extending state, the lower side surfaces of the two adsorption plates 1 can be abutted against the same plane by the adsorption plates 1 on the two sleeves translation mechanism 200.

Specifically, referring to fig. 2, in the case that the telescopic actuators 2 on the two sets of sleeve-translating mechanisms 200 are in the retracted state, the suction plate 1 is in the lifted state, and the suction plate 1 on the left side is lifted to a height higher than that of the suction plate 1 on the right side, so that the telescopic stroke of the telescopic actuator 2 on the sleeve-translating mechanism 200 on the left side is greater than that of the telescopic actuator 2 on the right side, and the sleeve-translating mechanism 200 on the right side extends downward by a distance through the support frame 110. Thus, the difference of the upward improvement degree is ensured, and the upward improvement degree can be propped against the same plane when the downward movement is performed.

The working process or principle of the utility model:

Referring to fig. 1 and 2, cloth for cutting sleeves is located in the middle of a frame 100 and extends along an axis of the device, one side of a wider width of an adsorption plate 1 of two sleeve translation mechanisms 200 is opposite, translation sliding mechanisms 3 on the two sleeve translation mechanisms 200 act to respectively align the adsorption plate 1 to the sleeve cloth, then telescopic actuating mechanisms 2 respectively extend, the adsorption plate 1 presses on corresponding sleeves, the adsorption plate 1 adsorbs the sleeves under the action of negative pressure, then the telescopic actuating mechanisms 2 respectively retract, the adsorption plate 1 and the sleeves are lifted upwards, then the translation sliding mechanisms 3 act reversely to respectively move the adsorption plate 1 above conveying belts on two sides of a garment body, then the telescopic actuating mechanisms 2 respectively extend, the negative pressure of the adsorption plate 1 is interrupted, and the sleeves are placed on the conveying belts.

Claims (10)

1. The utility model provides an isolation coat-sleeve stepping transfer mechanism, includes frame (100), its characterized in that: two sleeve translation mechanisms (200) are arranged on the frame (100) in parallel, each sleeve translation mechanism (200) comprises an adsorption plate (1), a telescopic actuating mechanism (2) and a translation sliding mechanism (3) which are sequentially connected from bottom to top, each translation sliding mechanism (3) drives the adsorption plate (1) to horizontally reciprocate, each telescopic actuating mechanism (2) drives the adsorption plate (1) to vertically reciprocate, the adsorption plates (1) on the two sleeve translation mechanisms (200) oppositely or back to back move, and each translation sliding mechanism (3) is connected with the frame (100) in an installation mode.

2. The isolation sleeve stepwise transfer mechanism of claim 1, wherein: the adsorption plate (1) is a hollow plate body, a plurality of adsorption holes (11) are formed in the lower side of the hollow plate body, and a suction interface (12) is formed in the upper side of the hollow plate body.

3. The isolation sleeve stepwise transfer mechanism of claim 2, wherein: the upper side of the adsorption plate (1) is provided with a reinforcing frame (13), the suction interface (12) is arranged on the reinforcing frame (13), and the reinforcing frame (13) is communicated with the inside of the adsorption plate (1).

4. The isolation sleeve stepwise transfer mechanism of claim 1, wherein: a plurality of telescopic actuating mechanisms (2) are arranged on the upper side of the adsorption plate (1), and the telescopic actuating mechanisms (2) are connected with the translation sliding mechanism (3) through a supporting structure (4).

5. The isolation sleeve stepwise transfer mechanism of claim 4, wherein: the support structure (4) comprises a first support plate (42), wherein second support plates (41) are respectively arranged at two ends of the lower side of the first support plate (42), a plurality of telescopic actuating mechanisms (2) are respectively arranged at the lower side of the second support plates (41), and the first support plate (42) is connected with the translation sliding mechanism (3).

6. The isolation sleeve stepwise transfer mechanism of claim 5, wherein: the translational sliding mechanisms (3) are provided with two sets, a third supporting plate (43) is further arranged on the upper side of the first supporting plate (42), and the third supporting plate (43) is connected with the two sets of translational sliding mechanisms (3).

7. The isolation sleeve stepwise transfer mechanism of claim 1, wherein: the translation sliding mechanism (3) is a linear sliding module, the linear sliding module comprises a sliding rail assembly (31) and a sliding block (32) arranged on the sliding rail assembly (31), a driver (33) is arranged on the sliding rail assembly (31), the driver (33) drives the sliding block (32) to reciprocate, and the telescopic actuating mechanism (2) is connected with the sliding block (32).

8. The isolation sleeve stepwise transfer mechanism of claim 6, wherein: the translation sliding mechanism (3) is a linear sliding module, the linear sliding module comprises a sliding rail assembly (31) and a sliding block (32) arranged on the sliding rail assembly (31), two sets of translation sliding mechanisms (3) are connected and driven through a transmission shaft (34), a driver (33) is arranged on one translation sliding mechanism (3), the driver (33) drives the sliding blocks (32) on the two sets of translation sliding mechanisms (3) to synchronously operate, and a third supporting plate (43) is connected with the sliding blocks (32).

9. The barrier sleeve stepwise transfer mechanism of claim 1 or 4, wherein: the telescopic actuating mechanism (2) is an air cylinder or an oil cylinder.

10. The isolation sleeve stepwise transfer mechanism of claim 1, wherein: when the telescopic actuating mechanism (2) is in a retracted state, the height of one adsorption plate (1) is higher than that of the other adsorption plate (1), and when the telescopic actuating mechanism (2) is in an extended state, the lower side surfaces of the two adsorption plates (1) can be propped against the same plane.