CN219057460U - Transmission mechanism capable of adapting to workpieces with multiple sizes - Google Patents

Abstract

The utility model provides a conveying mechanism capable of adapting to workpieces with multiple sizes, which comprises a conveying assembly and a receiving assembly, wherein a workpiece conveying channel is formed in the conveying assembly, the receiving assembly is arranged outside the conveying assembly, the workpieces can move onto the receiving assembly through the workpiece conveying channel, the receiving assembly comprises a first receiving structure and a second receiving structure, the first receiving structure and the second receiving structure are arranged at intervals along the direction of the workpiece conveying channel, and the first receiving structure has the dimension in the direction of the workpiece conveying channel. The transmission mechanism capable of adapting to the workpieces with multiple sizes is used for transmitting the workpieces through the conveying assembly, and carrying the workpieces on the conveying assembly through the carrying assembly, wherein the sizes of the first carrying structure and the second carrying structure are limited, so that the first carrying structure and the second carrying structure can be suitable for carrying the workpieces with different sizes.

Description

Transmission mechanism capable of adapting to workpieces with multiple sizes

Technical Field

The utility model relates to the field of workpiece transmission, in particular to a transmission mechanism for an adaptable multi-size workpiece for linen processing, wherein the linen processing comprises, but is not limited to, linen folding.

Background

The linen folding machine adopts the mechanical principle of combining electricity and gas phase to fold linen of various specifications into a rectangular flat machine, and is mainly used for hotel batch processing linen, time and labor are saved, wherein the conveying mechanism is arranged in the folding machine and is used for conveying the linen after folding on the folding machine.

In the use of the traditional conveying mechanism for the folding machine, the same-size conveying mechanism is adopted to convey the linen to cause larger energy loss due to different sizes of the linen, and the linen with larger size is easy to loosen in the conveying process due to the fact that the linen cannot be classified and conveyed according to different sizes, so that the folding effect of the produced linen is affected.

In view of the foregoing, there is an urgent need for a conveying mechanism capable of stably conveying workpieces of different sizes.

Disclosure of Invention

In order to solve the problem that the large-size linen is easy to loosen in the conveying process, the utility model provides a conveying mechanism capable of adapting to workpieces with multiple sizes.

According to one object of the present utility model, there is provided a transfer mechanism adaptable to a plurality of sizes of workpieces, comprising: the conveying assembly is provided with a workpiece conveying channel, the conveying assembly is externally provided with the bearing assembly, a workpiece can move to the bearing assembly through the workpiece conveying channel, the bearing assembly comprises a first bearing structure and a second bearing structure, the first bearing structure and the second bearing structure are arranged at intervals along the direction of the workpiece conveying channel, and the size of the first bearing structure in the direction of the workpiece conveying channel is larger than that of the second bearing structure in the direction of the workpiece conveying channel.

Preferably, the workpiece in the conveying channel has a workpiece conveying direction, and the first bearing structure and the second bearing structure are sequentially arranged along the workpiece conveying direction.

Preferably, the conveying mechanism further comprises a conveying assembly, the conveying assembly is arranged outside the bearing assembly, and the workpiece can move onto the conveying assembly through the bearing assembly.

Preferably, the receiving component is disposed above the conveying component near an end of the conveying component, and the first receiving structure is located at a dimension projected in a vertical direction of the conveying component, which is greater than a dimension projected in a vertical direction of the conveying component by the second receiving structure.

Preferably, the carrying assembly further comprises a plurality of conveying belts, the conveying belts are arranged on the first carrying structure and the second carrying structure, and workpieces on the first carrying structure and the second carrying structure can be transferred through the conveying belts.

Preferably, the conveyor belts are spaced apart in a manner facing the transfer assembly.

Preferably, the conveyor belt spacing distance on the first receiving structure is the same as the conveyor belt spacing distance on the second receiving structure, and the number of conveyor belts on the first receiving structure is greater than the number of conveyor belts on the second receiving structure.

Preferably, the upper end surface of the bearing assembly is horizontally arranged.

Compared with the prior art, the utility model has the beneficial effects that:

the transmission mechanism capable of adapting to the workpieces with multiple sizes is used for transmitting the workpieces through the conveying assembly, and carrying the workpieces on the conveying assembly through the carrying assembly, wherein the sizes of the first carrying structure and the second carrying structure are limited, so that the first carrying structure and the second carrying structure can be suitable for carrying the workpieces with different sizes.

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings.

Drawings

Fig. 1 is a schematic diagram of an embodiment of a conveying mechanism capable of adapting to multiple workpieces according to the present utility model.

In the figure: 100. a transport assembly; 200. a receiving assembly; 201. a first receiving structure; 202. a second receiving structure; 203. a conveyor belt; 300. and a transfer assembly.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the utility model defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the utility model.

Referring to fig. 1, the present utility model provides a technical solution: a transport mechanism adaptable to multiple size workpieces, comprising: the conveying assembly 100 and the bearing assembly 200, a workpiece conveying channel is arranged on the conveying assembly 100, the bearing assembly 200 is arranged outside the conveying assembly 100, a workpiece can move onto the bearing assembly 200 through the workpiece conveying channel, the bearing assembly 200 comprises a first bearing structure 201 and a second bearing structure 202, the first bearing structure 201 and the second bearing structure 202 are arranged at intervals along the direction of the workpiece conveying channel, and the dimension of the first bearing structure 201 in the direction of the workpiece conveying channel is larger than the dimension of the second bearing structure 202 in the direction of the workpiece conveying channel.

The workpieces are transported by the conveying assembly 100, and the workpieces on the conveying assembly 100 are received by the receiving assembly 200, wherein the sizes of the first receiving structure 201 and the second receiving structure 202 are limited, so that the first receiving structure 201 and the second receiving structure 202 can be suitable for receiving workpieces with different sizes.

It should be noted that, this transmission mechanism can be applied to the linen folding mechanism and use, and the work piece is the linen after folding, and wherein linen folding structure and this transmission structure's connection structure and publication number are: the cotton and linen folding machine used in the laundry of CN216514753U is of the same structure, is well known in the art and will not be described in detail here.

Further, the workpieces in the conveying channel have a workpiece conveying direction, and the first receiving structure 201 and the second receiving structure 202 are sequentially arranged along the workpiece conveying direction.

The workpieces move in the conveying channel along the workpiece conveying direction, wherein the arrangement sequence of the first bearing structure 201 and the second bearing structure 202 in the workpiece conveying direction is limited, so that the first bearing structure 201 with larger size can bear the workpieces with larger size preferentially, the reduction of the conveying distance of the workpieces with larger size is realized, the scattering of the workpieces with larger size in the conveying process is avoided, and the folding effect of the output workpieces is kept.

Further, the upper end surface of the receiving assembly 200 is horizontally disposed.

By setting the upper end surface of the receiving assembly 200 to be horizontal, the workpiece at the upper end of the receiving assembly 200 is prevented from being influenced by gravity, so that the position of the workpiece is offset, and the conveying effect of the workpiece on the device is prevented from being influenced.

In one embodiment of the present utility model, the number of the first receiving structures 201 is set to one, and the number of the second receiving structures 202 is set to two.

Further, the device further comprises a conveying assembly 300, wherein the conveying assembly 300 is arranged outside the bearing assembly 200, and the workpiece can move onto the conveying assembly 300 through the bearing assembly 200.

By arranging the conveying assembly 300, the conveying assembly 300 can further transfer the workpiece on the receiving assembly 200, and the workpiece is conveyed to a set position by the conveying assembly 300, so that the workpiece is convenient to further process.

In one embodiment of the present utility model, the transfer assembly 300 and publication number: the stacking device of the CN216514753U used for cotton and linen folding machines in the laundry is the same in structure, is the prior art and is not described in detail herein.

Further, the end of the receiving member 200 near the conveying member 300 is disposed above the conveying member 300, and the projected dimension of the first receiving structure 201 in the vertical direction of the conveying member 300 is larger than the projected dimension of the second receiving structure 202 in the vertical direction of the conveying member 300.

By extending the carrying assembly 200 above the conveying assembly 300, the workpiece on the carrying assembly 200 can fall into the upper end of the conveying assembly 300 under the action of gravity in the conveying process, wherein the size of the first carrying structure 201 and the size of the second carrying structure 202 above the conveying assembly 300 are further limited, and the workpiece with larger size can be stably transferred onto the conveying assembly 300 with the aid of the first carrying structure 201.

Specifically, the carrying assembly 200 further includes a plurality of conveying belts 203, the conveying belts 203 are disposed on the first carrying structure 201 and the second carrying structure 202, and the workpieces on the first carrying structure 201 and the second carrying structure 202 can be transferred by the conveying belts 203.

Wherein the connection structure and publication number between the conveyor belt 203 and the receiving assembly 200 are: the first conveyer belt connecting structure in the linen conveyer belt structure of the CN208700219U is the same as the prior art.

More specifically, the receiving component 200 includes a fixed receiving plate and a movable receiving plate, the fixed receiving plate and the upper end face of the movable receiving plate are flush, the fixed receiving plate and the movable receiving plate are sequentially arranged along a mode close to the conveying component 300, when the receiving component 200 works, a workpiece falls to the upper side of the fixed receiving plate, the workpiece moves towards the direction of the conveying component 300 through the conveying belt 203, when the workpiece moves to the upper side of the movable receiving plate, the conveying belt 203 stops moving, a push-pull structure is arranged between the fixed receiving plate and the movable receiving plate, the fixed receiving plate and the push-pull structure between the movable receiving plate can push the movable receiving plate to move towards the conveying component 300, when the end of the movable receiving plate moves to the side of the conveying component 300, the conveying belt 203 is started, and meanwhile, the workpiece falls down and is conveyed to the upper side of the conveying component under the action of the conveying belt 203 through the push-pull structure, and the push-pull structure is well-known in the prior art, and the prior art describes that the fixed receiving plate is in a stable connection.

Further, the conveyor belts 203 are spaced apart in a manner facing the transfer assembly 300.

Further, the conveyor belts 203 on the first receiving structure 201 are spaced apart by the same distance as the conveyor belts 203 on the second receiving structure 202, and the number of conveyor belts 203 on the first receiving structure 201 is greater than the number of conveyor belts 203 on the second receiving structure 202.

By limiting the number of the conveying belts 203 on the first supporting structure 201 and the number of the conveying belts 203 on the second supporting structure 202, the conveying belts 203 on the first supporting structure 201 have better supporting effect on workpieces than the conveying belts 203 on the second supporting structure 202, and can stably convey large-size workpieces.

The working principle is as follows; when the transmission mechanism is applied to the linen folding mechanism, the conveying assembly 100 corresponds to a blanking part on the linen folding mechanism;

the workpiece moves in the workpiece conveying channel, when the workpiece moves to be above the corresponding first bearing structure 201, the workpiece with larger size falls down, and when the workpiece moves to be above the corresponding second bearing structure 202, the workpiece with smaller size falls down onto the second bearing structure 202;

the conveyer belt 203 on the bearing assembly 200 is started, the conveyer belt 203 drives the workpiece to move towards the direction of the conveying assembly 300, when the workpiece moves to the position above the movable bearing plate, the conveyer belt 203 stops moving, a push-pull structure between the fixed bearing plate and the movable bearing plate can push the movable bearing plate to move towards the conveying assembly 300, when the tail end of the movable bearing plate moves to the side, away from the bearing assembly 200, of the conveying assembly 300, the conveyer belt 203 is started, meanwhile, the movable bearing plate resets under the action of the push-pull structure, the workpiece falls down and is tiled above the conveying assembly 300 under the action of the conveyer belt 203 and the movable bearing plate, the conveying assembly 300 is further started, and the conveying assembly 300 drives the workpiece to move to a preset stacking position to finish the conveying of the workpiece.

In summary, the workpieces are transported by the conveying assembly 100, and the workpieces on the conveying assembly 100 are received by the receiving assembly 200, wherein the sizes of the first receiving structure 201 and the second receiving structure 202 are limited, so that the first receiving structure 201 and the second receiving structure 202 can be suitable for receiving workpieces with different sizes.

The above-described embodiments are only for illustrating the technical spirit and features of the present utility model, and it is intended to enable those skilled in the art to understand the content of the present utility model and to implement it accordingly, and the scope of the present utility model as defined by the present embodiments should not be limited only by the present embodiments, i.e. equivalent changes or modifications made in accordance with the spirit of the present utility model will still fall within the scope of the present utility model.

Claims (8)

1. A transfer mechanism adaptable to multiple size workpieces, comprising: the conveying assembly (100) and the bearing assembly (200), a workpiece conveying channel is arranged on the conveying assembly (100), the bearing assembly (200) is arranged outside the conveying assembly (100), a workpiece can move to the bearing assembly (200) through the workpiece conveying channel, the bearing assembly (200) comprises a first bearing structure (201) and a second bearing structure (202), the first bearing structure (201) and the second bearing structure (202) are arranged at intervals along the direction of the workpiece conveying channel, and the size of the first bearing structure (201) in the direction of the workpiece conveying channel is larger than the size of the second bearing structure (202) in the direction of the workpiece conveying channel.

2. A transport mechanism for adaptable multi-sized workpieces as defined in claim 1, wherein: the workpieces in the conveying channel have a workpiece conveying direction, and the first bearing structure (201) and the second bearing structure (202) are sequentially arranged along the workpiece conveying direction.

3. A transport mechanism for adaptable multi-sized workpieces as defined in claim 1, wherein: the device also comprises a conveying assembly (300), wherein the conveying assembly (300) is arranged outside the bearing assembly (200), and a workpiece can move onto the conveying assembly (300) through the bearing assembly (200).

4. A transport mechanism for adaptable multi-sized workpieces as defined in claim 3, wherein: the end of the receiving component (200) close to the conveying component (300) is arranged above the conveying component (300), and the first receiving structure (201) is located at the projection size of the conveying component (300) in the vertical direction and is larger than the projection size of the second receiving structure (202) located at the conveying component (300) in the vertical direction.

5. A transport mechanism for adaptable multi-sized workpieces as defined in claim 3, wherein: the bearing assembly (200) further comprises a plurality of conveying belts (203), the conveying belts (203) are arranged on the first bearing structure (201) and the second bearing structure (202), and workpieces on the first bearing structure (201) and the second bearing structure (202) can be transferred through the conveying belts (203).

6. A transport mechanism for adaptable multi-sized workpieces as defined in claim 5, wherein: the conveyor belts (203) are spaced apart in a manner facing the transfer assembly (300).

7. A transport mechanism for adaptable multi-sized workpieces as defined in claim 6, wherein: the conveyor belts (203) on the first receiving structure (201) are spaced apart by the same distance as the conveyor belts (203) on the second receiving structure (202), and the number of conveyor belts (203) on the first receiving structure (201) is greater than the number of conveyor belts (203) on the second receiving structure (202).

8. A transport mechanism for adaptable multi-sized workpieces as defined in claim 1, wherein: the upper end face of the bearing assembly (200) is horizontally arranged.

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