CN204957410U - A storage case for green silicon carbide raw materials ratio - Google Patents

Abstract

The utility model provides a material storage box used for proportioning green silicon carbide raw materials, which comprises a box body (1), and the box body (1) is provided with a material inlet (11) and a material outlet (12) , the feed port (11) is provided with a sieve plate (111), and the storage box of the present application solves the problem that the feed port of the existing storage box cannot screen the mixture.

Description

A storage box for the ratio of green silicon carbide raw materials

technical field

The utility model belongs to the technical field of chemical ingredients, in particular to a material storage box used for proportioning green silicon carbide raw materials.

Background technique

In the proportioning process of the existing green silicon carbide raw materials, the mixed material that has been stirred in the stirring box will drop to the storage box. Material, since the feed port of the storage box does not have any screening equipment, therefore, it is easy to make the lumpy mixture enter the storage box. In the subsequent use process, there are problems of inconvenient use and poor use effect. Based on the above problems, this The application provides a material storage box used for proportioning green silicon carbide raw materials, which solves the problem that the feed inlet of the existing material storage box cannot screen the mixed material.

Contents of the invention

The purpose of the utility model is to provide a green silicon carbide raw material ratio storage box with simple structure and convenient operation, so as to solve the problem that the feed port of the existing storage box cannot screen the mixed material.

In order to solve the above problems, the application provides a storage box for the proportioning of green silicon carbide raw materials, including a box body (1), and the box body (1) is provided with a material inlet (11) and a material outlet port (12), and a sieve plate (111) is arranged on the feed port (11).

As a preferred solution of the present application, a baffle plate (121) is provided on the discharge port (12), and the material baffle plate (121) is arranged inside or outside the discharge port (12).

As a preferred solution of the present application, when the material baffle (121) is arranged on the outside of the discharge port (12);

The material baffle (121) comprises a long-arm baffle (1211) and a short-arm baffle (1212), and the long-arm baffle (1211) is arranged on one side of the discharge port (12), and the The short-arm baffle (1212) is arranged on the side adjacent to or opposite to the long-arm baffle (1211), and the extension directions of the long-arm baffle (1211) and the short-arm baffle (1212) are consistent with their corresponding sides, so A discharge opening (1213) is formed between the long arm baffle (1211) and the short arm baffle (1212);

The baffle plate (121) comprises a long arm baffle (1211) and/or a short arm baffle (1212), and the long arm baffle (1211) and/or the short arm baffle (1212) are arranged on the Each side of the discharge port (12) forms a columnar structure, and a discharge port (1213) is formed between the long arm baffle (1211) and/or the short arm baffle (1212);

When the material baffle (121) is arranged inside the discharge port (12), the material baffle (121) is provided with a spiral-shaped feeding trough (1214).

As a preferred solution of the present application, when the material baffle (121) is arranged on the outside of the outlet (12), at least one of the material baffles (121) is arranged on the outlet of the outlet through an adjustment button (1215). Outside the feed port (12), the size of the feed port (1213) is adjusted by the adjusting button (1215).

As a preferred solution of the present application, the sieve plate (111) is in any one of a circular structure or a polygonal structure, and the sieve holes on the sieve plate (111) are in any one of a hole-like structure or a grid structure. kind.

As a preferred solution of the present application, a drive mechanism is connected to the sieve plate (111), the drive mechanism includes a drive motor (112) and a transmission rod (113), and one end of the transmission rod (113) is connected to the screen plate (111), the other end is connected with the drive motor (112), the drive motor (112) drives the transmission rod (113) to reciprocate, and then drives the sieve plate (111) in the feeding mouth (11) upward reciprocating motion

The utility model provides a green silicon carbide raw material ratio storage box with simple structure and convenient operation. Compared with the prior art, the application sets a sieve plate at the feeding port of the storage box. When discharging the material box, the mixture can be screened, which solves the problem that the material inlet of the existing storage box cannot screen the mixture, and prevents the blocky mixture in the mixing box from entering the storage box. In the process, it leads to the problems of inconvenient use and poor use effect.

Description of drawings

Fig. 1 is the schematic view of the structure of a storage box provided with a sieve plate at the feed inlet provided by the embodiment of the utility model;

Fig. 2 is a schematic diagram of the structure of a sieve plate provided by the embodiment of the present invention;

Fig. 3 is a schematic diagram of another sieve plate structure provided by the embodiment of the present invention;

Fig. 4 is a schematic diagram of another sieve plate structure provided by the embodiment of the present invention;

Fig. 5 is a schematic structural diagram of a storage box provided with a baffle plate at the discharge port provided by an embodiment of the present invention;

Fig. 6 is a structural schematic diagram of another storage box provided with a baffle plate at the discharge port provided by the embodiment of the present invention;

Fig. 7 is a structural schematic diagram of another storage box provided with a baffle plate at the discharge port provided by the embodiment of the utility model;

Fig. 8 is a structural schematic diagram of a spiral groove provided on the baffle plate provided by the embodiment of the present invention.

reference sign

Box 1, feed port 11, discharge port 12, sieve plate 111, drive motor 112, transmission rod 113, material baffle 121, long arm baffle 1211, short arm baffle 1212, feeding port 1213, feeding Slot 1214, adjusting buckle 1215.

detailed description

In order to make the purpose, technical solutions and advantages of the present utility model clearer, the embodiments of the present utility model will be described in detail below in conjunction with the accompanying drawings.

Example 1:

This embodiment provides a storage box for the ratio of green silicon carbide raw materials. The discharge box includes a box body 1, and the box body 1 is provided with a material inlet 11 and a material outlet 12. The material inlet 11 is provided with a sieve plate 111, and the sieve plate 111 is connected with a drive mechanism, the drive mechanism includes a drive motor 112 and a transmission rod 113, and in this embodiment, the drive motor 112 is dual-purpose. Motor, one end of the transmission rod 113 is connected to at least one side wall of the sieve plate 111, and the other end is connected to the drive motor 112. When in use, when the drive motor 112 is started to rotate positively and negatively, the drive rod 113 is driven to reciprocate. Further, the sieve plate 111 is driven to reciprocate on the feed port 11 , see FIG. 1 , which is a schematic structural diagram of a storage box provided with a sieve plate 111 at the feed port provided by this embodiment. Therefore, adopting the material storage box in this embodiment not only solves the problem that the material inlet 11 of the existing material storage box cannot screen the mixed material, but also makes the material inlet 11 screen the mixed material more automatically.

Further, in this embodiment, preferably, the sieve plate 111 is in any one of a circular structure or a polygonal structure, and the sieve holes on the sieve plate 111 are in any one of a hole-like structure or a grid structure , referring to Figs. 2-4, which are structural schematic diagrams of three kinds of sieve plates 111 provided in this embodiment.

Example 2:

Compared with Embodiment 1, in order to avoid the problem of non-concentrated blanking at the discharge port 12, this embodiment is provided with a baffle plate 121 on the discharge port 12, and the material baffle plate 121 is arranged on the outside of the discharge port 12 , the baffle plate 121 includes a long arm baffle 1211 and a short arm baffle 1212, the long arm baffle 1211 is arranged on one side of the discharge port 12, and the short arm baffle 1212 is arranged on the same side as the long arm baffle. The plates 1211 are on adjacent or opposite sides, and the extension direction of the long-arm baffle 1211 and the short-arm baffle 1212 is consistent with the corresponding side, that is, the long-arm baffle 1211 and the short-arm baffle 1212 are in a non-parallel state, A discharge opening 1213 is formed between the long-arm baffle 1211 and the short-arm baffle 1212 ; see FIG. 5 , which is a structural schematic diagram of the storage box discharge opening 12 provided in this embodiment. In this embodiment, by setting a material baffle plate 121 outside the discharge port 12, the problem of non-concentrated feeding of the existing discharge port 12 is avoided.

Example 3:

Compared with Embodiment 2, the difference of this embodiment is that, preferably, the baffle 121 includes a long arm baffle 1211 and/or a short arm baffle 1212, and the long arm baffle 1211 and/or the short arm baffle 1212 are respectively arranged on each side of the discharge port 12, and form a columnar structure (see Figure 6), that is, the long-arm baffles 1211 and/or the short-arm baffles 1212 are arranged in parallel, and the long-arm baffles 1211 and/or the short arm baffle plate 1212 forms a larger blanking opening 1213, thus not only solving the problem of non-concentrated loading of the existing blanking opening 1213, but also further avoiding the problem of blockage of the discharge opening 12 question.

Example 4:

Compared with Embodiment 2 or 3, in order to facilitate the opening and closing of the discharge port 12, in this embodiment, the material baffle plate 121 is arranged on the inner side of the discharge port 12 (see FIG. 7 ), and the material baffle plate 121 is provided with The material chute 1214 in a spiral structure (see Figure 8), through the material baffle plate 121 of the spiral structure, the raw material at the discharge port 12 is spirally dropped by pressing the structure of the material chute 1214 during the falling process, thus avoiding The problem of non-concentrated feeding at the feeding port 1213 of the existing storage box is solved.

Example 5:

Compared with Embodiment 2 or 3, in order to avoid the problem that the discharge port 1213 formed between the baffles is prone to blockage during the discharge process, in this embodiment, at least one of the baffles is preferably set at the discharge port through the adjustment button 1215 12, adjust the size of the feed opening 1213 through the adjustable buckle, and the adjustable buckle 133 includes any one of screws or hinges.

Claims (10)

1. A material storage box for green silicon carbide raw material proportioning, comprising casing (1), said casing (1) is provided with feed inlet (11) and discharge outlet (12), its feature In that, a sieve plate (111) is arranged on the feed inlet (11). 2. the storage box for green silicon carbide raw material proportioning as claimed in claim 1, is characterized in that, described discharge opening (12) is provided with material stopper (121), and described material stopper (121) 121) is arranged inside or outside the discharge port (12). 3. The storage box for green silicon carbide raw material proportioning as claimed in claim 2, characterized in that: When the material baffle (121) is arranged on the outside of the discharge port (12); The material baffle (121) comprises a long-arm baffle (1211) and a short-arm baffle (1212), and the long-arm baffle (1211) is arranged on one side of the discharge port (12), and the The short-arm baffle (1212) is arranged on the side adjacent to or opposite to the long-arm baffle (1211), and the extension directions of the long-arm baffle (1211) and the short-arm baffle (1212) are consistent with their corresponding sides, so A discharge opening (1213) is formed between the long arm baffle (1211) and the short arm baffle (1212); Or, the baffle plate (121) comprises a long arm baffle (1211) and/or a short arm baffle (1212), and the long arm baffle (1211) and/or the short arm baffle (1212) are arranged on Each side of the discharge port (12) forms a columnar structure, and a discharge port (1213) is formed between the long-arm baffles (1211) and/or the short-arm baffles (1212). 4. The material storage box for the proportioning of green silicon carbide raw materials according to claim 2, characterized in that, when the baffle plate (121) is arranged on the inner side of the discharge port (12), the baffle A feeding chute (1214) in a spiral structure is provided on the material plate (121). 5. The storage box for green silicon carbide raw material proportioning as claimed in claim 2 or 3, characterized in that, when the baffle plate (121) is arranged on the outside of the discharge port (12) , at least one of the baffle plates (121) is arranged outside the discharge port (12) through an adjustment button (1215), and the size of the discharge port (1213) is adjusted through the adjustment button (1215). 6. The material storage box for green silicon carbide raw material proportioning according to any one of claims 1-4, characterized in that, the sieve plate (111) has any one of a circular structure or a polygonal structure , the sieve holes on the sieve plate (111) are any one of a hole-like structure or a grating structure. 7. The material storage box for green silicon carbide raw material proportioning as claimed in claim 5, characterized in that, the sieve plate (111) is any one of a circular structure or a polygonal structure, and the sieve plate (111) The sieve holes on (111) are any one of a hole-like structure or a grid structure. 8. The storage box for green silicon carbide raw material proportioning according to any one of claims 1-4, characterized in that, the sieve plate (111) is connected with a drive mechanism, and the drive mechanism includes a drive Motor (112) and transmission rod (113), one end of described transmission rod (113) is connected with described sieve plate (111), and the other end is connected with described driving motor (112), and described driving motor (112) drives The transmission rod (113) reciprocates, and then drives the sieve plate (111) to reciprocate on the feeding port (11). 9. The material storage box for green silicon carbide raw material proportioning as claimed in claim 5, characterized in that, the sieve plate (111) is connected with a drive mechanism, and the drive mechanism includes a drive motor (112) and Transmission rod (113), one end of described transmission rod (113) is connected with described sieve plate (111), and the other end is connected with described driving motor (112), and described driving motor (112) drives described transmission rod ( 113) to reciprocate, and then drive the sieve plate (111) to reciprocate on the feed port (11). 10. The material storage box for green silicon carbide raw material proportioning as claimed in claim 6, characterized in that, the sieve plate (111) is connected with a drive mechanism, and the drive mechanism includes a drive motor (112) and Transmission rod (113), one end of described transmission rod (113) is connected with described sieve plate (111), and the other end is connected with described driving motor (112), and described driving motor (112) drives described transmission rod ( 113) to reciprocate, and then drive the sieve plate (111) to reciprocate on the feed port (11).