CN219837522U - Chip storage box for numerical control machine tool - Google Patents

Abstract

The utility model relates to the field of numerical control machine tools, in particular to a chip storage box for a numerical control machine tool, which comprises an outer box body, wherein an inner cavity and a feed inlet for waste materials to enter the inner cavity are formed in the outer box body; the inner box body is provided with at least two box outlets which are used for sliding the inner box body out of the inner cavity; the utility model aims to overcome the defects of the prior art and provide the chip storage box for the numerical control machine tool, which can clean the chip storage box on the premise of not influencing the continuous operation of the numerical control machine tool.

Description

Chip storage box for numerical control machine tool

Technical Field

The utility model relates to the field of numerical control machine tools, in particular to a chip storage box for a numerical control machine tool.

Background

The numerical control machine tool is an automatic machine tool provided with a program control system, is mainly used for solving the problems of complex, precise, small batch and multiple kinds of part processing, and is a flexible and high-efficiency automatic machine tool.

However, a great deal of metal scraps can be generated during processing of the numerical control machine tool, and the metal scraps need to be cleaned, so that a great deal of research is carried out on the metal scraps by a person skilled in the art, wherein the patent with the publication number of CN215659224U discloses that the metal scraps can be automatically swept into a scraps storage box by utilizing an electrically-driven brush in the patent with the publication number of CN215659224U, however, the mode avoids manually cleaning the scraps, however, when the scraps storage box is cleaned or replaced, the machine tool needs to be shut down to avoid scraps from being discharged to the outer side of the scraps storage box, which is very unfavorable for continuous processing of the numerical control machine tool and quite affects the processing efficiency. Therefore, how to design a chip storage box for a numerical control machine tool, the chip storage box can be cleaned on the premise of not affecting the continuous operation of the numerical control machine tool, and the continuous research is still needed.

Disclosure of Invention

In view of the above, the utility model aims to overcome the defects of the prior art and provide a chip storage box for a numerical control machine tool, which can clean the chip storage box on the premise of not influencing the continuous operation of the numerical control machine tool.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

the chip storage box for the numerical control machine tool comprises an outer box body, wherein an inner cavity and a feed inlet for waste to enter the inner cavity are formed in the outer box body;

the inner box body is provided with at least two box outlets which are used for sliding the inner box body out of the inner cavity;

the inner box body is divided into a first state and a second state, in the first state, at least two inner box bodies which are in butt joint are placed in parallel in the inner cavity, at least one inner box body is located under the feeding port, along with the sliding of the two inner box bodies, one inner box body is separated from the inner part of the inner cavity from the box outlet, the other inner box body is used for continuously taking in waste, and the inner box body is switched into the second state.

Preferably, a receiving plate for changing the sectional area of the feeding hole is arranged in the inner cavity, one of two opposite sides of the receiving plate is hinged with the side wall of the inner cavity, and the other side of the receiving plate is positioned in the inner box or is abutted with the opening edge of the inner box.

Preferably, the other two sides of the receiving plate are respectively fixedly provided with a side plate for preventing scraps from sliding to the outer side of the inner box body.

Preferably, a connecting groove is provided on one of two opposite sides in the sliding direction of the inner case, and a connecting rod for hooking with the connecting groove on the adjacent inner case is provided on the other side.

Preferably, the inner box body is further provided with a first baffle and a second baffle for closing a gap between two adjacent inner box bodies, the first baffle and the second baffle are respectively arranged on two opposite sides in the sliding direction of the inner box body, and at least one upper end face of the first baffle and at least one upper end face of the second baffle are flush with the upper end face of the inner box body.

Preferably, when the adjacent two inner boxes are connected to receive the scraps, the first baffle is abutted with the second baffle of the adjacent inner box, and the second baffle is located right below the first baffle.

Preferably, the first baffle and the second baffle are both made of elastic materials.

Compared with the prior art, the utility model has the advantages that:

when the waste disposal box is used, two inner boxes are pushed into the inner cavity from the box inlet, the two inner boxes are abutted, when waste enters from the feed inlet, the waste enters the inner box near the box outlet, when the waste inside the inner box needs to be cleaned, the two inner boxes are pushed to enable the inner box near the box outlet to be separated from the box outlet, the inner box at the rear side continues to receive the waste, and a new inner box is pushed into the box inlet.

Through the structure, the inner box body can be replaced under the condition that the numerical control machine tool is not stopped, so that continuous operation of the numerical control machine tool is realized, and the working efficiency of the numerical control machine tool is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of an axial cross-sectional structure of the present utility model;

FIG. 3 is a schematic view of a first state of the present utility model;

fig. 4 is a schematic structural view of the second state of the present utility model.

Reference numerals: 10. an outer case; 11. an inner cavity; 12. a feed inlet; 13. a box inlet; 14. a box outlet; 15. a receiving plate; 16. a side plate; 20. an inner case; 21. a connecting groove; 22. a connecting rod; 23. a first baffle; 24. and a second baffle.

Detailed Description

The following detailed description of the utility model is provided in connection with the accompanying drawings to facilitate understanding and grasping of the technical scheme of the utility model.

The embodiment provides a digit control machine tool is with holding bits case can realize holding the clearance of bits case under the prerequisite that does not influence digit control machine tool continuous operation.

As shown in fig. 1 and 2, in order to facilitate continuous operation of the numerically-controlled machine tool, the numerically-controlled machine tool comprises an outer box 10, wherein an inner cavity 11 and an inner box 20 for allowing waste materials to enter the inner cavity 11 are formed on the outer box 10;

the inner box body 20 is provided with at least two box inlets 13 for sliding the inner box body 20 into the inner cavity 11, and box outlets 14 for sliding the inner box body 20 out of the inner cavity 11;

further, as shown in fig. 2 and 4, in order to facilitate the efficiency of the inner box 20 in collecting the waste material and to facilitate the concentration of the waste material, a material collecting plate 15 for changing the cross-sectional area of the material fed from the material feeding port 12 is disposed inside the inner cavity 11, one of two opposite sides of the material collecting plate 15 is hinged to the side wall of the inner cavity 11, the other side of the material collecting plate 15 is located inside the inner box 20 or abuts against the opening edge of the inner box 20, and two side plates 16 for preventing the chips from sliding to the outer side of the inner box 20 are respectively fixed on the other two sides of the material collecting plate 15; specifically, the linear distance between the two side plates 16 is smaller than the linear distance between the two opposite side walls of the inner case 20.

The inner box 20 is divided into a first state and a second state, in the first state, at least two abutted feed inlets 12 are placed in parallel in the inner cavity 11, the two inner boxes 20 are located right below the feed inlets 12 to receive waste, the rear inner box 20 pushes the receiving plate 15 to rotate along with the sliding of the two inner boxes 20, the front inner box 20 is separated from the inner cavity 11 from the box outlet 14, the waste slides from the upper side of the receiving plate 15, the other inner box 20 continues to receive the waste, the inner box 20 is switched into the second state, and at the moment, a new inner box 20 is pushed in from the inner part of the star inner cavity 11 at the box inlet 13; when one inner box 20 receives waste, the waste is convenient to concentrate, and when two inner boxes 20 receive waste, the efficiency of collecting the waste is convenient to promote.

Further, as shown in fig. 2 to 4, in order to avoid separation of the adjacent two inner boxes 20, a connection groove 21 is provided at one of opposite sides in the sliding direction of the inner boxes 20, and a connection rod 22 for hooking with the connection groove 21 on the adjacent inner box 20 is provided at the other side; specifically, the connecting groove 21 is L-shaped, and when two inner boxes 20 are connected, a longer part of the L-shape of the connecting groove 21 is inserted into the connecting rod 22 to connect two adjacent inner boxes 20.

Further, as shown in fig. 3 and 4, in order to prevent the scraps from falling out of the inner case 20, a first baffle 23 and a second baffle 24 for closing a gap between two adjacent inner cases 20 are further fixed on the inner case 20, the first baffle 23 and the second baffle 24 are respectively disposed on two opposite sides in the sliding direction of the inner case 20, and an upper end face of at least one of the first baffle 23 and the second baffle 24 is flush with an upper end face of the inner case 20; when the adjacent two inner boxes 20 are connected to receive scraps, the first baffle plate 23 is abutted against the second baffle plate 24, and the second baffle plate 24 is located right below the first baffle plate 23.

When gaps appear between two adjacent inner boxes 20, as the first baffle plate 23 is positioned under the second baffle plate 24 of the adjacent inner boxes 20, the first baffle plate 23 and the second baffle plate 24 can bear the scraps, and the scraps are prevented from falling out of the boxes, the arrangement can amplify the processing errors of the inner boxes 20, and the inner boxes 20 are convenient to process and produce.

Preferably, the first baffle 23 and the second baffle 24 are made of elastic materials, specifically, the elastic materials are rubber, and the arrangement of the rubber materials effectively avoids deformation possibly caused by collision between the first baffle 23 and the second baffle 24, so that the service life of the inner box 20 is prolonged.

The foregoing is only exemplary of the utility model, and many other embodiments of the utility model are possible, and all modifications and variations of the utility model are intended to fall within the scope of the utility model.

Claims (7)

1. The chip storage box for the numerical control machine tool is characterized by comprising an outer box body (10), wherein an inner cavity (11) and a feed inlet (12) for waste to enter the inner cavity (11) are formed in the outer box body (10);

the inner box body (20) with an upward opening, a box inlet (13) for the inner box body (20) to slide into the inner cavity (11) and a box outlet (14) for the inner box body (20) to slide out of the inner cavity (11), wherein the inner box body (20) is provided with at least two boxes;

the inner box body (20) is divided into a first state and a second state, in the first state, at least two abutted inner box bodies (20) are placed in parallel in the inner cavity (11), at least one inner box body (20) is located under the feeding port (12), along with the sliding of the two inner box bodies (20), one inner box body (20) is separated from the inner part of the inner cavity (11) from the box outlet (14), the other inner box body (20) continues to collect waste, and the inner box body (20) is switched into the second state.

2. The chip storage box for the numerical control machine tool according to claim 1, wherein a receiving plate (15) for changing the feeding sectional area of the feeding port (12) is arranged in the inner cavity (11), one of two opposite sides of the receiving plate (15) is hinged with the side wall of the inner cavity (11), and the other side of the receiving plate (15) is positioned in the inner box (20) or is abutted with the opening edge of the inner box (20).

3. The chip storage box for the numerical control machine tool according to claim 2, wherein the other two sides of the receiving plate (15) are respectively fixedly provided with a side plate (16) for preventing chips from sliding to the outer side of the inner box body (20).

4. A chip storage box for a numerical control machine tool according to any one of claims 1 to 3, characterized in that a connecting groove (21) is provided on one of opposite sides in the sliding direction of the inner box body (20), and a connecting rod (22) for hooking with the connecting groove (21) on the adjacent inner box body (20) is provided on the other side.

5. The chip storage box for the numerical control machine tool according to claim 1, wherein a first baffle (23) and a second baffle (24) for closing a gap between two adjacent inner boxes (20) are further fixedly arranged on the inner boxes (20), the first baffle (23) and the second baffle (24) are respectively arranged on two opposite sides in the sliding direction of the inner boxes (20), and at least one upper end face of the first baffle (23) and at least one upper end face of the second baffle (24) are flush with the upper end face of the inner boxes (20).

6. The chip storage box for a numerical control machine tool according to claim 5, wherein when two adjacent inner boxes (20) are connected to each other to receive chips, the first baffle (23) is abutted against the second baffle (24) of the adjacent inner boxes (20), and the second baffle (24) is located directly below the first baffle (23).

7. The chip storage box for the numerical control machine tool according to claim 5 or 6, wherein the first baffle plate (23) and the second baffle plate (24) are made of elastic materials.