CN216537908U - Automatic feeding device for nano heat-insulating plate production line - Google Patents

Abstract

The utility model discloses an automatic feeding device for a nano heat insulation plate production line, which comprises a processing box for a nano heat insulation plate, wherein a heater is arranged on the processing box, a feeding box is arranged at the top of the processing box, a feeding hopper is arranged at the top of the feeding box, a material storage cavity is arranged in the feeding box, a transmission shaft is rotatably connected in the material storage cavity through a bearing on the feeding box, a stirring plate is arranged on the transmission shaft, a feeding channel is arranged at the bottom of the material storage cavity between the feeding box and the processing box, a rotating shaft is rotatably connected on the side surface of the feeding channel through a bearing on the feeding box, and a sealing plate is fixedly sleeved on the rotating shaft; has the beneficial effects that: according to the utility model, the sealing plate and the control assembly are additionally arranged on the feeding box, and the control assembly drives the sealing plate to rotate and open under the condition that the processing box is preheated, so that the feeding of the raw material powder of the nano heat-insulating plate is controlled conveniently, the automation degree is high, the stirring and mixing effect of the raw material powder of the nano heat-insulating plate is ensured, and the production quality of the nano heat-insulating plate is improved.

Description

Automatic feeding device for nano heat-insulating plate production line

Technical Field

The utility model relates to the technical field of production of nano heat-insulating plates, in particular to an automatic feeding device for a nano heat-insulating plate production line.

Background

The high-performance heat insulation material has important significance for energy conservation and consumption reduction in the industrial field, particularly in the fields of metallurgy, building materials, chemical engineering, thermal power and the like with medium-high temperature and high energy consumption, and the main materials used for manufacturing the nano heat insulation plate are as follows: the nano heat insulation plate is formed by mixing and pressing the three materials, namely nano silicon dioxide, silicon carbide, alkali-free glass fiber and the like, and effectively avoids heat transfer caused by air convection, so that the heat conductivity coefficient can be greatly reduced.

In the existing production process of the nano heat insulation plate, raw material powder needs to be heated and stirred, but the raw material powder of the nano heat insulation plate is added into a box for processing the nano heat insulation plate before being preheated, so that the raw material powder of the nano heat insulation plate is not well stirred and mixed, and the production quality of the nano heat insulation plate is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an automatic feeding device for a nano heat insulation plate production line, which aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a device of automatic material of throwing of nanometer heat-insulating shield production line, is including the processing case that is used for nanometer heat-insulating shield, be provided with the heater on the processing case, the top of processing case is provided with the batch charging case, the top of batch charging case is provided with into the hopper, be provided with the storage cavity in the batch charging case, it is connected with the transmission shaft to be located the storage cavity in the rotation through the bearing on the batch charging case, be provided with the stirring board on the transmission shaft, the bottom that is located the storage cavity between batch charging case and the processing case is provided with the pan feeding passageway, the side that is located the pan feeding passageway on the batch charging case rotates through the bearing and is connected with the pivot, fixed the cup joint has the shrouding in the pivot, be provided with the gear in the pivot, the holding tank has been seted up to the bottom of batch charging case, it sets up in the holding tank has automatic pivoted control assembly to throw the batch charging case.

Preferably, the storage cavity is cylindrical cavity structure, the sealed motor that is provided with of material case is run through to the one end of transmission shaft, the stirring board is provided with a plurality ofly, and a plurality of stirring boards are the circumference around the transmission shaft and distribute.

Preferably, the closing plate is attached to the surface of the feeding channel, and the accommodating groove is communicated with the inside of the processing box.

Preferably, a material guide plate is arranged on the other side of the feeding box, which is located on the feeding channel, and the material guide plate is obliquely arranged and attached to the upper surface of the sealing plate.

Preferably, the control assembly comprises a micropore block, the micropore block is welded on the feeding box, an air bag is arranged at the top of the micropore block, and a moving block is arranged at the top of the air bag.

Preferably, a rack is arranged on the side face of the moving block, the rack is meshed with the gear, and an elastic body is arranged between the top of the moving block and the accommodating groove.

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

1. according to the utility model, the blanking plate and the control assembly are additionally arranged on the feeding box, and the control assembly drives the blanking plate to rotate and open under the condition of preheating the processing box, so that the feeding of the raw material powder of the nano heat-insulating plate is controlled conveniently, the automation degree is high, the stirring and mixing effect of the raw material powder of the nano heat-insulating plate is ensured, and the production quality of the nano heat-insulating plate is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of the batch tank of the present invention;

FIG. 3 is a schematic structural diagram of a control assembly according to the present invention;

fig. 4 is an enlarged schematic view of a portion a of fig. 3 according to the present invention.

In the figure: a processing box 1; a heater 2; a feeding box 3; a storage cavity 31; a drive shaft 32; a motor 33; a stirring plate 34; feeding into a hopper 4; a feeding channel 5; a material guide plate 51; a rotating shaft 6; a gear 61; a closing plate 7; a housing tank 8; a microporous block 81; an air bag 82; a moving block 83; a rack 84; and an elastic body 85.

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 to 4, the present invention provides a technical solution: an automatic feeding device for a nanometer heat insulation plate production line comprises a processing box 1 for a nanometer heat insulation plate, a heater 2 is fixedly installed on the processing box 1, a feeding box 3 is welded at the top of the processing box 1, a feeding hopper 4 is welded at the top of the feeding box 3, a storage cavity 31 is formed in the feeding box 3, the storage cavity 31 is of a cylindrical cavity structure, a transmission shaft 32 is rotatably connected to the feeding box 3 in the storage cavity 31 through a bearing, a motor 33 is hermetically installed at one end of the transmission shaft 32 and penetrates through the feeding box 3, the output end of the motor 33 is welded with the transmission shaft 32, a plurality of stirring plates 34 are welded on the transmission shaft 32, the plurality of stirring plates 34 are circumferentially distributed around the transmission shaft 32, a feeding channel 5 is arranged at the bottom of the storage cavity 31 between the feeding box 3 and the processing box 1, and the stirring plates 34 are attached to the inner wall of the storage cavity 31, when heater 2 heating preheats the inside of processing case 1, form relative confined space between stirring board 34 and the transmission shaft 32, prevent to process the inside heat dissipation of case 1, the rotation of transmission shaft 32 and stirring board 34 prevents that the nanometer heat-insulating shield powder raw materials in the feed box 3 from agglomerating and blockking up the entry simultaneously.

The side surface of the feeding box 3 positioned on the feeding channel 5 is rotatably connected with a rotating shaft 6 through a bearing, a sealing plate 7 is fixedly sleeved on the rotating shaft 6, the sealing plate 7 is attached to the surface of the feeding channel 5, a gear 61 is fixedly sleeved on the rotating shaft 6, a material guide plate 51 is welded on the other side of the feeding channel 5 on the feeding box 3, the material guide plate 51 is obliquely arranged and attached to the upper surface of the sealing plate 7, the material guide plate 51 guides the nano heat insulation plate powder raw material on one hand and limits the sealing plate 7 on the other hand, the sealing plate 7 is prevented from rotating upwards to influence the sealing effect of the sealing plate 7, the nano heat insulation plate powder raw material is light in weight, the nano heat insulation plate powder raw material falling on the sealing plate 7 cannot drive the sealing plate 7 to rotate under the elastic action of an elastic body 85, a holding tank 8 is arranged at the bottom of the feeding box 3, and the holding tank 8 is communicated with the inside of the processing box 1, it has automatic pivoted control assembly to lie in the holding tank 8 on the case of throwing 3 and set up, control assembly includes micropore piece 81, micropore piece 81 welds on the case of throwing 3, gasbag 82 has been placed at the top of micropore piece 81, gasbag 82 satisfies expend with heat and contract with cold fundamental principle, when preheating in the inside of processing case 1, the heat transmits to gasbag 82 through the hole of micropore piece 81, make it thermal expansion, the top laminating of gasbag 82 has movable block 83, the side welding of movable block 83 has rack 84, intermeshing between rack 84 and the gear 61, fixedly connected with elastomer 85 between the top of movable block 83 and the holding tank 8, subsequent control assembly of being convenient for of the spring action of elastomer 85 resets.

The working principle is as follows: when the device is in actual use, nano heat insulation plate powder raw materials are added into a feeding box 3 through a feeding hopper 4, the nano heat insulation plate powder raw materials fall into a storage cavity 31, a heater 2 is started to heat the interior of a processing box 1, a motor 33 is started, the output end of the motor 33 drives a transmission shaft 32 and a stirring plate 34 to rotate, the nano heat insulation plate powder raw materials are stirred, the nano heat insulation plate powder raw materials in the feeding box 3 are prevented from agglomerating to block an inlet, a relatively sealed space is formed between the stirring plate 34 and the transmission shaft 32, heat dissipation in the processing box 1 is prevented, before heating is finished, a sealing plate 7 is attached to the surface of a feeding channel 5, due to the fact that the heating temperature rises, the heat is transmitted to an air bag 82 through the pores of a micropore block 81 to be heated and expanded, a moving block 83 is driven to move upwards, at the moment, a rack 84 drives a gear 61 to rotate, and then pivot 6 and seal block all rotate, and the nanometer heat-insulating shield raw materials that fall on shrouding 7 get into the inside of processing case 1 through pan feeding passageway 5, and the feeding of automatic control nanometer heat-insulating shield raw materials powder guarantees the stirring of nanometer heat-insulating shield raw materials powder and mixes the effect to improve the quality of nanometer heat-insulating shield production.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a device of automatic material of throwing of nanometer insulation panels production line, is including processing case (1) that is used for nanometer insulation panels, its characterized in that: the processing box is characterized in that a heater (2) is arranged on the processing box (1), a feeding box (3) is arranged at the top of the processing box (1), a feeding hopper (4) is arranged at the top of the feeding box (3), a storage cavity (31) is arranged in the feeding box (3), a transmission shaft (32) is rotatably connected in the storage cavity (31) on the feeding box (3) through a bearing, a stirring plate (34) is arranged on the transmission shaft (32), a feeding channel (5) is arranged at the bottom of the storage cavity (31) between the feeding box (3) and the processing box (1), a rotating shaft (6) is rotatably connected on the side surface of the feeding channel (5) on the feeding box (3) through a bearing, a sealing plate (7) is fixedly sleeved on the rotating shaft (6), a gear (61) is arranged on the rotating shaft (6), an accommodating groove (8) is formed in the bottom of the feeding box (3), and a control assembly capable of automatically rotating is arranged in the accommodating groove (8) on the feeding box (3).

2. The automatic feeding device for the nano insulation board production line according to claim 1, characterized in that: storage cavity (31) are cylindrical cavity structures, the sealed motor (33) that is provided with of batch charging case (3) is run through to the one end of transmission shaft (32), stirring board (34) are provided with a plurality ofly, and a plurality of stirring boards (34) are the circumference around transmission shaft (32) and distribute.

3. The automatic feeding device for the nano insulation board production line according to claim 1, characterized in that: the sealing plate (7) is attached to the surface of the feeding channel (5), and the accommodating groove (8) is communicated with the inside of the processing box (1).

4. The automatic feeding device for the nano insulation board production line according to claim 1, characterized in that: the feeding box (3) is provided with a material guide plate (51) at the other side of the feeding channel (5), and the material guide plate (51) is obliquely arranged and attached to the upper surface of the sealing plate (7).

5. The automatic feeding device for the nano insulation board production line according to claim 1, characterized in that: the control assembly comprises a micropore block (81), the micropore block (81) is welded on the feeding box (3), an air bag (82) is arranged at the top of the micropore block (81), and a moving block (83) is arranged at the top of the air bag (82).

6. The automatic feeding device for the nano insulation board production line according to claim 5, wherein the automatic feeding device comprises: the side of the moving block (83) is provided with a rack (84), the rack (84) is meshed with the gear (61), and an elastic body (85) is arranged between the top of the moving block (83) and the accommodating groove (8).

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