CN220412121U - Transmission device - Google Patents

Abstract

The utility model provides a transmission device, comprising: the conveying platform is used for conveying powder, is obliquely arranged relative to the horizontal plane, and the lower end of the conveying platform is a discharging end; the airflow circulation cavity is arranged below the transmission platform; the blowing assembly is communicated with the airflow circulation cavity, so that blowing is performed to the airflow circulation cavity through the blowing assembly, and airflow drives at least part of the transmission platform to shake, so that powder on the transmission platform is transmitted to the discharging position. The utility model solves the problem of lower powder loading efficiency in the prior art.

Description

Transmission device

Technical Field

The utility model relates to the technical field of powder transmission, in particular to a transmission device.

Background

In the field of glass fiber production, different kinds of stones are crushed and ground to form powder, and the glass fiber raw material is formed by using the proportion of the different kinds of powder.

In the powder production process of building stones, when powder preparation is accomplished the back needs loading transportation, generally through screw conveyer sack unloading in the prior art, the feed opening needs manual control break-make, and screw conveyer fault rate is high, and conveying speed is slow, and the phenomenon of easy emergence running material leads to powder loading efficiency low.

Disclosure of Invention

The utility model mainly aims to provide a conveying device to solve the problem of low powder loading efficiency in the prior art.

In order to achieve the above object, the present utility model provides a transmission apparatus comprising: the conveying platform is used for conveying powder, is obliquely arranged relative to the horizontal plane, and the lower end of the conveying platform is a discharging end; the airflow circulation cavity is arranged below the transmission platform; the blowing assembly is communicated with the airflow circulation cavity, so that blowing is performed to the airflow circulation cavity through the blowing assembly, and airflow drives at least part of the transmission platform to shake, so that powder on the transmission platform is transmitted to the discharging position.

Further, the inclination angle of the transmission platform relative to the horizontal plane is 5 ° to 9 °; the transmission device further includes: the conveying cylinder is obliquely arranged relative to the horizontal plane, and the conveying platform and the airflow circulation cavity are respectively arranged in the conveying cylinder; the fixed component is at least partially arranged on the material conveying cylinder, and the end part of the transmission platform is connected with the fixed component so as to fix the transmission platform in the material conveying cylinder through the fixed component.

Further, the feed delivery cartridge includes: a first housing; the second shell is opposite to the first shell and fixedly connected with the first shell through a fastener, at least part of the airflow circulation cavity is positioned in the second shell, and the airflow circulation cavity extends along the extending direction of the second shell; the end part of the transmission platform is clamped between the first shell and the second shell, and the transmission platform is connected with the first shell and/or the second shell through the fixing component.

Further, a communication hole is formed in the side wall of the second shell, and the blowing component is arranged on the second shell and is communicated with the airflow circulation cavity through the communication hole.

Further, the communication holes are multiple, and the communication holes are arranged at intervals along the extending direction of the second shell; the blowing assemblies are in one-to-one correspondence and communicated with the communication holes.

Further, the bottom of the material conveying cylinder is provided with an air inlet channel communicated with the airflow circulation cavity; at least part of the blowing component is arranged on the material conveying cylinder, and a blowing port of the blowing component is communicated with the air inlet channel.

Further, the higher end of the material conveying cylinder is a feeding end, and the air inlet channel is positioned at the feeding end of the material conveying cylinder.

Further, the transmission device further includes: the feed bin is arranged above the feed conveying cylinder, a feed channel communicated with the feed bin is arranged on the feed conveying cylinder, and a discharge hole of the feed channel is opposite to the conveying platform; wherein, the gas outlet of the gas inlet channel is staggered with the discharge hole of the feed channel.

Further, transmission device still includes a material conveying section of thick bamboo, and transmission platform and air current circulation chamber set up respectively in a material conveying section of thick bamboo, and transmission device still includes: the charging hopper is arranged at the discharge end of the material conveying cylinder, a discharge channel is arranged in the charging hopper, and the discharge channel is communicated with the material conveying cylinder; wherein the charging hopper is movably arranged relative to the position of the feeding cylinder.

Further, the charging hopper includes: the joint is connected with the material conveying cylinder; the telescopic pipe section is communicated with one end of the joint, which is far away from the material conveying cylinder, and is arranged in a telescopic way; the end, far away from the joint, of the telescopic pipe section is communicated with the blanking hopper; wherein, the joint, the telescopic pipe section and the discharging hopper are respectively provided with a discharging channel.

By applying the technical scheme of the utility model, the conveying device comprises a conveying platform, an airflow circulation cavity and an air blowing assembly, wherein the conveying platform is used for conveying powder, the conveying platform is obliquely arranged relative to the horizontal plane, and the lower end of the conveying platform is a discharge end; the airflow circulation cavity is arranged below the transmission platform; the blowing assembly is communicated with the airflow circulation cavity, so that the blowing assembly blows air into the airflow circulation cavity, and the airflow drives at least part of the transmission platform to shake, so that powder on the transmission platform is transmitted to the discharging position. The setting is through blowing in the air current to the air current circulation intracavity like this, make transmission platform take place to shake under the effect of air current, combine transmission platform to incline for the horizontal plane to set up, make the powder remove to the lower one end of transmission platform gradually under self gravity effect and transmission platform's shake effect, finally make the powder output by the discharge end, the whole process need not the start and stop that the manual control material was carried, and when the subassembly of blowing stops blowing, stop the material that can be timely, the condition of taking place the material that runs is avoided, compare in screw conveying's mode, transmission platform's fault rate is lower, the maintenance of being convenient for, the loading efficiency of powder has been improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. In the drawings:

fig. 1 shows a schematic structural view of an embodiment of a transmission device according to the utility model; and

fig. 2 shows a schematic structural view of a loading hopper of a conveyor according to the utility model.

Wherein the above figures include the following reference numerals:

1. a transmission platform; 2. an airflow circulation chamber; 3. an air blowing assembly; 4. a feed delivery cylinder; 40. an air intake passage; 5. a storage bin; 41. a feed channel; 42. a first housing; 43. a second housing; 6. a charging hopper; 60. a discharge channel; 61. a joint; 62. a telescoping tube section; 63. and (5) discharging a hopper.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The utility model will be described in detail below with reference to the drawings in connection with embodiments.

Referring to fig. 1 and 2, the present utility model provides a transmission device, including: the conveying platform 1 is used for conveying powder, the conveying platform 1 is obliquely arranged relative to the horizontal plane, and the lower end of the conveying platform 1 is a discharge end; the airflow circulation cavity 2 is arranged below the transmission platform 1; the blowing assembly 3 is communicated with the airflow circulation cavity 2, so that the blowing assembly 3 blows air into the airflow circulation cavity 2, and the air flow drives at least part of the transmission platform 1 to shake, so that powder on the transmission platform 1 is transmitted to a discharging position.

The conveying device comprises a conveying platform 1, an airflow circulation cavity 2 and an air blowing assembly 3, wherein the conveying platform 1 is used for conveying powder, the conveying platform 1 is obliquely arranged relative to a horizontal plane, and the lower end of the conveying platform 1 is a discharge end; the airflow circulation cavity 2 is arranged below the transmission platform 1; the blowing component 3 is communicated with the airflow circulation cavity 2, so that the blowing component 3 blows air into the airflow circulation cavity 2, so that the air flow drives at least part of the transmission platform 1 to shake, and powder on the transmission platform 1 is transmitted to a discharging position. The setting is through blowing in the air current to the air current circulation chamber 2 in the in-process of carrying the powder like this, make transmission platform 1 take place to shake under the effect of air current, combine transmission platform 1 to incline for the horizontal plane to set up, make the powder remove to the lower one end of transmission platform 1 gradually under self gravity effect and transmission platform 1's shake effect, finally make the powder output by the discharge end, the whole process need not the start and stop that the manual control material was carried, and when blowing subassembly 3 stops blowing, the condition of taking place the material of running has been avoided, compared in the mode of screw conveying, transmission platform 1's fault rate is lower, the maintenance of being convenient for, the loading efficiency of powder has been improved.

Specifically, the inclination angle of the transport platform 1 with respect to the horizontal plane is 5 ° to 9 °. In an exemplary embodiment, the transport platform 1 is inclined at an angle of 7 ° relative to the horizontal to facilitate the downward flow of powder. Here, the inclination angle of the conveying platform 1 with respect to the horizontal plane refers to an angle between the conveying end face of the conveying platform 1 and the horizontal plane.

In an implementation, the transmission device further includes: the material conveying cylinder 4 is obliquely arranged relative to the horizontal plane, and the conveying platform 1 and the airflow circulation cavity 2 are respectively arranged in the material conveying cylinder 4; the fixed subassembly, fixed subassembly's at least part sets up on defeated feed cylinder 4, and the tip and the fixed subassembly of transmission platform 1 are connected to fix transmission platform 1 in defeated feed cylinder 4 through fixed subassembly. Preferably, the fixing assembly is a fastening bolt or a clamping member to fix the edge of the transport platform 1.

In the present application, the feed cylinder 4 comprises: a first housing 42; the second shell 43 is opposite to the first shell 42 and fixedly connected through a fastener, at least part of the airflow cavity 2 is positioned in the second shell 43, and the airflow cavity 2 extends along the extending direction of the second shell 43; wherein the end of the transmission platform 1 is sandwiched between the first housing 42 and the second housing 43, and the transmission platform 1 is connected with the first housing 42 and/or the second housing 43 by a fixing assembly. The inner wall surface of the first casing 42 is an arc surface, the inner wall surface of the second casing 43 is an arc surface, and the first casing 42 and the second casing 43 are utilized to connect, so that not only can the transmission platform 1 be directly fixed, but also the airflow cavity 2 is directly arranged in the second casing 43, and the structure is simple and the implementation is convenient.

In one embodiment provided by the utility model, a communication hole is arranged on the side wall of the second shell 43, and the air blowing assembly 3 is arranged on the second shell 43 and is communicated with the air flow cavity 2 through the communication hole. By blowing air into the air flow chamber 2, the fluidity of the powder on the transfer platform 1 is increased.

Wherein, a plurality of communication holes are arranged at intervals along the extending direction of the second shell 43; the plurality of blowing assemblies 3 are arranged, and the plurality of blowing assemblies 3 are communicated with the plurality of communication holes in a one-to-one correspondence manner, so that each blowing assembly 3 is respectively connected with each communication hole in series. The setting is blown to each position of transmission platform 1 like this to improve transmission platform 1's shake frequency, improve the conveying efficiency of powder.

In another embodiment provided by the utility model, the bottom of the material conveying cylinder 4 is provided with an air inlet channel 40 communicated with the airflow circulation cavity 2; at least part of the blowing assembly 3 is arranged on the material conveying cylinder 4, and a blowing port of the blowing assembly 3 is communicated with the air inlet channel 40. Preferably, the higher end of the feed cylinder 4 is the feed end, and the air inlet channel 40 is located at the feed end of the feed cylinder 4. When the blowing component 3 runs, air flows from the feeding end of the material conveying cylinder 4 to the discharging end, and the flowing speed of powder is increased under the action of the air flows, so that the conveying efficiency of the materials is improved.

In an implementation, the transmission device further includes: the feed bin 5 is arranged above the feed conveying cylinder 4, a feed channel 41 communicated with the feed bin 5 is arranged on the feed conveying cylinder 4, and a discharge port of the feed channel 41 is opposite to the conveying platform 1; wherein the air outlet of the air inlet channel 40 is staggered with the discharge outlet of the feed channel 41. Wherein, the feed channel 41 is provided with a control valve, and the on-off of the feed channel 41 is controlled by the control valve. In addition, the air outlet of the air inlet channel 40 is staggered with the discharge outlet of the feed channel 41, so that the air flow blown out of the air inlet channel 40 is prevented from being blown into the feed channel 41, and the powder output is prevented from being influenced.

Further, the transmission device further comprises a material conveying cylinder 4, the transmission platform 1 and the airflow cavity 2 are respectively arranged in the material conveying cylinder 4, and the transmission device further comprises: the charging hopper 6 is arranged at the discharge end of the material conveying cylinder 4, a discharge channel 60 is arranged in the charging hopper 6, and the discharge channel 60 is communicated with the material conveying cylinder 4; wherein the charging hopper 6 is arranged in a position movable relative to the feed cylinder 4. This is arranged so that the powder on the transfer platform 1 is output to the transport vehicle via the hopper 6.

Specifically, the charging hopper 6 includes: a joint 61 connected to the feed cylinder 4; a telescopic tube section 62, which is communicated with one end of the joint 61 away from the feed delivery cylinder 4, the telescopic tube section 62 being telescopically arranged; a discharging hopper 63, wherein one end of the telescopic pipe section 62 away from the joint 61 is communicated with the discharging hopper 63; wherein the joint 61, the telescopic pipe section 62 and the discharging hopper 63 are respectively provided with a discharging channel 60. By the telescopic action of the telescopic pipe section 62, when powder on the transport carrier is piled up, the position of the telescopic pipe section 62 can be adjusted to realize continuous blanking.

In the present application, the blowing assembly 3 is preferably a blower or a fan; the conveying platform 1 is cloth, the cloth is clamped between the first shell 42 and the second shell 43 and is respectively connected with the first shell 42 and the second shell 43 through fastening bolts, so that the cloth is kept tensioned in the material conveying cylinder 4, and powder is convenient to move on the surface of the cloth.

From the above description, it can be seen that the above embodiments of the present utility model achieve the following technical effects:

the conveying device comprises a conveying platform 1, an airflow circulation cavity 2 and an air blowing assembly 3, wherein the conveying platform 1 is used for conveying powder, the conveying platform 1 is obliquely arranged relative to a horizontal plane, and the lower end of the conveying platform 1 is a discharge end; the airflow circulation cavity 2 is arranged below the transmission platform 1; the blowing component 3 is communicated with the airflow circulation cavity 2, so that the blowing component 3 blows air into the airflow circulation cavity 2, so that the air flow drives at least part of the transmission platform 1 to shake, and powder on the transmission platform 1 is transmitted to a discharging position. The setting is through blowing in the air current to the air current circulation chamber 2 in the in-process of carrying the powder like this, make transmission platform 1 take place to shake under the effect of air current, combine transmission platform 1 to incline for the horizontal plane to set up, make the powder remove to the lower one end of transmission platform 1 gradually under self gravity effect and transmission platform 1's shake effect, finally make the powder output by the discharge end, the whole process need not the start and stop that the manual control material was carried, and when blowing subassembly 3 stops blowing, the condition of taking place the material of running has been avoided, compared in the mode of screw conveying, transmission platform 1's fault rate is lower, the maintenance of being convenient for, the loading efficiency of powder has been improved.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A transmission apparatus, comprising:

the powder conveying device comprises a conveying platform (1) and a powder conveying device, wherein the conveying platform (1) is obliquely arranged relative to a horizontal plane, and the lower end of the conveying platform (1) is a discharging end;

the airflow circulation cavity (2) is arranged below the transmission platform (1);

the blowing assembly (3), the blowing assembly (3) is communicated with the airflow circulation cavity (2), so that the blowing assembly (3) blows air into the airflow circulation cavity (2), and the air flow drives at least part of the conveying platform (1) to shake, so that powder on the conveying platform (1) is conveyed to a discharging position.

2. The transfer device according to claim 1, characterized in that the transfer platform (1) is inclined at an angle of 5 ° to 9 ° with respect to the horizontal; and/or

The transmission device further includes:

the conveying cylinder (4) is obliquely arranged relative to the horizontal plane, and the conveying platform (1) and the airflow circulation cavity (2) are respectively arranged in the conveying cylinder (4);

the fixed component is at least partially arranged on the material conveying cylinder (4), and the end part of the transmission platform (1) is connected with the fixed component so as to fix the transmission platform (1) in the material conveying cylinder (4) through the fixed component.

3. The transfer device according to claim 2, wherein the feed cylinder (4) comprises:

a first housing (42);

the second shell (43) is opposite to the first shell (42) and fixedly connected through a fastener, at least part of the airflow cavity (2) is positioned in the second shell (43), and the airflow cavity (2) extends along the extending direction of the second shell (43);

the end part of the transmission platform (1) is clamped between the first shell (42) and the second shell (43), and the transmission platform (1) is connected with the first shell (42) and/or the second shell (43) through the fixing assembly.

4. A transfer device according to claim 3, characterized in that a communication hole is provided in a side wall of the second housing (43), and the air blowing assembly (3) is provided in the second housing (43) and communicates with the air flow chamber (2) through the communication hole.

5. The transmission device according to claim 4, wherein the communication holes are plural, and plural communication holes are provided at intervals along the extending direction of the second casing (43);

the number of the blowing assemblies (3) is multiple, and the blowing assemblies (3) are communicated with the communication holes in a one-to-one correspondence manner.

6. The transfer device according to claim 2, characterized in that the bottom of the feed cylinder (4) is provided with an air inlet channel (40) communicating with the airflow through-cavity (2);

at least part of the blowing component (3) is arranged on the material conveying cylinder (4), and a blowing port of the blowing component (3) is communicated with the air inlet channel (40).

7. The transfer device according to claim 6, wherein the higher end of the feed cylinder (4) is a feed end, and the air inlet channel (40) is located at the feed end of the feed cylinder (4).

8. The transmission apparatus according to claim 6, characterized in that the transmission apparatus further comprises:

the feed bin (5) is arranged above the feed conveying cylinder (4), a feed channel (41) communicated with the feed bin (5) is arranged on the feed conveying cylinder (4), and a discharge hole of the feed channel (41) is opposite to the conveying platform (1);

the air outlet of the air inlet channel (40) is staggered with the discharge outlet of the feeding channel (41).

9. The transfer device according to claim 1, further comprising a transfer cylinder (4), the transfer platform (1) and the airflow through-cavity (2) being arranged in the transfer cylinder (4), respectively, the transfer device further comprising:

the charging hopper (6) is arranged at the discharge end of the material conveying cylinder (4), a discharge channel (60) is arranged in the charging hopper (6), and the discharge channel (60) is communicated with the material conveying cylinder (4);

wherein the charging hopper (6) is arranged in a position movable relative to the feed delivery cylinder (4).

10. The transfer device according to claim 9, wherein the charging hopper (6) comprises:

a joint (61) connected with the feed delivery cylinder (4);

a telescopic pipe section (62) communicated with one end of the joint (61) far away from the material conveying cylinder (4), wherein the telescopic pipe section (62) is arranged in a telescopic way;

a blanking hopper (63), wherein one end of the telescopic pipe section (62) far away from the joint (61) is communicated with the blanking hopper (63);

wherein the joint (61), the telescopic pipe section (62) and the discharging hopper (63) are respectively provided with the discharging channel (60).