CN216661340U - Positioning conveying caching mechanism for side die sorting - Google Patents

Abstract

The utility model discloses a positioning and conveying cache mechanism for side forms sorting, which comprises a cache frame, wherein a first conveying part for positioning the side forms and conveying the side forms forwards at equal intervals is arranged on the cache frame along the length direction of the cache frame, a second conveying part avoiding the conveying track position of the side forms is also arranged on the cache frame, and a power output end on the cache frame drives the second conveying part and the first conveying part to generate synchronous conveying action; the second conveying part is provided with receiving modules which move synchronously along with the second conveying part and sensing modules which sense the receiving modules and then send speed reduction stop signals to the power output end, and the distance between every two adjacent receiving modules is equal to the conveying distance of the upper side die of the first conveying part. The utility model ensures that the conveying distance of the first conveying part is a fixed distance each time, and ensures the positioning, conveying and caching of the side die.

Description

Positioning conveying caching mechanism for side die sorting

Technical Field

The utility model relates to the field of building prefabricated parts, in particular to a positioning, conveying and caching mechanism for side formwork sorting.

Background

In the production process of the prefabricated parts, the side forms are generally required to be assembled into a specific shape to form a prefabricated part mold so as to cast the prefabricated parts with the required shape. After the poured concrete is vibrated, maintained and the like, the side die is removed through a demolding process.

After the side forms are sorted and the types of the side forms are judged, the side forms need to be positioned and then conveyed to wait for the next mold distribution process, however, the process is completed without an automatic step, and therefore the solution is needed urgently.

Disclosure of Invention

In order to avoid and overcome the technical problems in the prior art, the utility model provides a side die sorting, positioning, conveying and caching mechanism. The utility model realizes the positioning, conveying and caching of the side forms and is convenient for taking and using during subsequent die distribution.

In order to achieve the purpose, the utility model provides the following technical scheme:

a positioning and conveying caching mechanism for side forms sorting comprises a caching frame, wherein a first conveying part for positioning the side forms and conveying the side forms forwards at equal intervals is arranged on the caching frame along the length direction of the caching frame, a second conveying part avoiding the conveying track position of the side forms is further arranged on the caching frame, and a power output end on the caching frame drives the second conveying part and the first conveying part to generate synchronous conveying action; the second conveying part is provided with receiving modules which synchronously move along with the second conveying part and sensing modules which sense the receiving modules and then send speed reduction stop signals to the power output end, and the distance between every two adjacent receiving modules is equal to the conveying distance of the upper die of the first conveying part.

As a still further scheme of the utility model: the power output end is a driving motor, and a motor shaft of the driving motor drives the driving gears of the first conveying part and the second conveying part to synchronously rotate.

As a further scheme of the utility model: first conveying department and second conveying department are end to end's gear chain structure, the gear model and the chain pitch homogeneous phase of first conveying department and second conveying department are the same.

As a still further scheme of the utility model: and the first conveying part is provided with positioning blocks in clamping fit with the side dies, and the positioning blocks are arranged at equal intervals.

As a still further scheme of the utility model: the second conveying part is provided with deceleration signal receiving pieces at equal intervals, the interval between the adjacent deceleration signal receiving pieces is equal to the conveying interval of the side die on the first conveying part, and the deceleration signal receiving pieces are receiving modules.

As a still further scheme of the utility model: and the positioning block is provided with a V-shaped notch to be matched with the chamfered edge of the side die.

As a still further scheme of the utility model: the buffer storage frame is provided with an adjusting rod for adjusting the tension degree of the first conveying part.

As a still further scheme of the utility model: the distance between the cache racks is in an arithmetic progression.

As a still further scheme of the utility model: the buffer storage frames are arranged in parallel at intervals, and the distance between every two adjacent buffer storage frames is gradually increased along the arrangement direction of the buffer storage frames so as to adapt to the conveying of the side forms with different lengths.

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

1. when the side forms are conveyed and positioned on the cache frame, the first conveying part conveys the side forms, the second conveying part and the first conveying part synchronously convey the side forms, when the sensing module on the second conveying part senses a signal of the receiving module, a deceleration stop signal is sent to the power output end, at the moment, the first conveying part stops, the side forms are conveyed again after being lifted and positioned next time, the process is repeated, and therefore the conveying distance of the first conveying part each time is guaranteed to be a fixed distance, and the positioning conveying cache of the side forms is guaranteed.

2. According to the utility model, the first conveying part and the second conveying part are designed into gear chain mechanisms with the same gear type and chain pitch, and the power output end adopts the driving motor to drive the gears of the first conveying part and the second conveying part to synchronously run, so that the accuracy of each conveying distance of the first conveying part is ensured; the positioning blocks arranged at equal intervals are arranged on the first conveying part, so that the side die is stably conveyed; the arrangement of the adjusting rod ensures that the chains of the first conveying part and the second conveying part can keep the same tension degree.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the second conveying part of the present invention.

In the figure:

3. a cache shelf;

31. a second conveying section; 311. a sensing module; 312. a receiving module;

32. a power output end;

33. a first conveying section; 331. positioning blocks;

34. and adjusting the rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-2, in an embodiment of the present invention, a positioning and conveying buffer mechanism for separating side forms, buffer frames 3 are arranged in parallel, and the number of the buffer frames matches with the length of the side forms.

The power output end 32 on the buffer frame 3 drives the first conveying part 33 and the second conveying part 31 to synchronously operate.

The frame body of the buffer frame 3 is provided with a first conveying part 33, and the side wall of the buffer frame 3 is fixed with a second conveying part 31.

The first conveying section 33 and the second conveying section 31 are both of a gear chain structure, and the gear type chain pitches of both conveying sections are the same.

The power take-off 32 can alternatively be a drive motor, the motor shaft of which passes through the sets of buffer holders 3 arranged in parallel, the drive gears of both transport sections being fitted on the motor shaft of the drive motor.

The chain of the first conveying part 33 is provided with positioning blocks 331 at equal intervals, and the positioning blocks 331 can clamp the side forms.

The positioning block 331 is shaped to position the sideforms on the first conveying portion 33, and the sideforms are perpendicular to the buffer racks 3 during the conveying process and form an included angle of ninety degrees.

The top of the positioning block 331 is provided with a V-shaped notch, the tip of the notch faces downwards and is arranged corresponding to the side edge of the side form.

The side wall of the buffer storage rack 3 is provided with an adjusting rod 34 matched with the chain of the first conveying part 33, the adjusting rod 34 is a telescopic rod, and the first conveying part 33 chain is driven to move while the first conveying part 33 chain is stretched and contracted, so that the first conveying part 33 chain is tensioned or loosened.

The sensing module 311 on the second conveying part 31 is used for sensing the signal of the receiving module 312.

The second conveying part 31 is preferably a double-row chain, the receiving modules 312 are installed at the center of the chain, and the spacing between the receiving modules 312 is equal to the spacing between the positioning blocks 331.

When the first conveying part 33 and the second conveying part 31 operate synchronously, the sensing module 311 sends a deceleration stop signal to the motor immediately after sensing the signal of the receiving module 312, and the motor drives the first conveying part 33 to decelerate and stop receiving the side forms.

After the side forms are placed on the positioning block 331, the driving motor is started again and drives the two conveying portions to start conveying again, after the sensing module 311 senses the signal of the receiving module 312, a deceleration stop signal is sent to the driving motor again, and the first conveying portion 33 receives a new side form after deceleration stop.

The receiving module 312 is certainly selected as a deceleration signal receiving piece, and the sensing module 311 is a sensor matched with the deceleration signal receiving piece in model.

The first conveying section 33 and the second conveying section 31 may be conveyor belts.

The above process is repeated to ensure that the first conveying part 33 advances at a fixed interval in a mode of first accelerating and then decelerating every time, and the side die conveying distance is always accurate.

Along the installation direction of the buffer storage frames 3, the distance between the buffer storage frames 3 is gradually increased to match the conveying of the side forms with different lengths.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (9)

1. A positioning and conveying caching mechanism for side forms sorting is characterized by comprising a caching frame (3), wherein first conveying parts (33) for positioning the side forms and conveying the side forms forwards at equal intervals are arranged on the caching frame (3) along the length direction of the caching frame, second conveying parts (31) avoiding the conveying track positions of the side forms are further arranged on the caching frame (3), and a power output end (32) on the caching frame (3) drives the second conveying parts (31) and the first conveying parts (33) to generate synchronous conveying action; the second conveying part (31) is provided with receiving modules (312) which move synchronously with the second conveying part (31) and sensing modules (311) which sense the receiving modules (312) and send speed reduction stop signals to the power output end (32), and the distance between every two adjacent receiving modules (312) is equal to the conveying distance of the upper side die of the first conveying part (33).

2. The positioning and conveying caching mechanism for the side forms sorting according to claim 1, wherein the first conveying part (33) and the second conveying part (31) are both in an end-to-end gear chain structure, and the gear models and the chain pitches of the first conveying part (33) and the second conveying part (31) are the same.

3. The positioning and conveying buffer mechanism for the side forms sorting according to claim 2, wherein the power output end (32) is a driving motor, and a motor shaft of the driving motor drives the driving gears of the first conveying part (33) and the second conveying part (31) to rotate synchronously.

4. The side form sorting, positioning and conveying caching mechanism according to any one of claims 1 to 3, wherein positioning blocks (331) matched with the side forms in a clamping mode are arranged on the first conveying portion (33), and the positioning blocks (331) are arranged at equal intervals.

5. The positioning and conveying caching mechanism for the side forms sorting according to claim 4, wherein a V-shaped notch is formed in the positioning block (331) to be matched with the chamfered edge of the side form.

6. The side die sorting, positioning and conveying buffer mechanism according to any one of claims 1 to 3, wherein deceleration signal receiving pieces are arranged on the second conveying part (31) at equal intervals, the interval between adjacent deceleration signal receiving pieces is equal to the side die conveying interval on the first conveying part (33), and the deceleration signal receiving pieces are the receiving modules (312).

7. The positioning and conveying buffer mechanism for the side forms sorting according to any one of claims 1 to 3, wherein an adjusting rod (34) for adjusting the tension degree of the first conveying part (33) is arranged on the buffer frame (3).

8. The side form sorting, positioning and conveying buffer mechanism according to any one of claims 1 to 3, wherein the buffer racks (3) are arranged in parallel at intervals, and the distance between adjacent buffer racks (3) is gradually increased along the arrangement direction of the buffer racks (3) so as to adapt to the conveying of the side forms with different lengths.

9. The positioning and conveying buffer mechanism for side die sorting according to claim 8, wherein the spacing between the buffer racks (3) is gradually increased in an arithmetic progression.

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