CN216334907U - Feeding device for producing inorganic active thermal insulation mortar - Google Patents

Abstract

The utility model belongs to the technical field of thermal insulation mortar, and particularly relates to a feeding device for producing inorganic active thermal insulation mortar, which comprises a feeding machine, wherein a conveying hopper is arranged below one end of the feeding machine, a feeding hopper is arranged at one end of the conveying hopper far away from the feeding machine, a sealing plate is connected to the lower part inside the feeding hopper through a control mechanism, and the control mechanism comprises a top plate, a lifting frame, a connecting shaft, an extension plate, an eccentric block, a supporting frame and a connecting rod; when the inside material of feeder is too much, can clockwise rotation operation board, make the closing plate up-move under the cooperation of the inside roof of control mechanism, crane, connecting axle, extension board, eccentric block, support frame and connecting rod, the in-process that moves up at the closing plate can reduce the open area between conveyer bucket and the feeder hopper, and then can avoid more materials to flow into the inside of feeder through the conveyer bucket through blockking of closing plate, avoid the inside more materials of piling up of feeder.

Description

Feeding device for producing inorganic active thermal insulation mortar

Technical Field

The utility model belongs to the technical field of thermal insulation mortar production, and particularly relates to a feeding device for producing inorganic active thermal insulation mortar.

Background

The heat-insulating mortar is a premixed dry powder mortar prepared by mixing various light materials as aggregates, cement as a cementing material and some modified additives through stirring by a production enterprise, the heat-insulating mortar is a building material for constructing a heat-insulating layer on the surface of a building, an inorganic heat-insulating mortar material heat-insulating system is fireproof and non-combustible, and can be widely used for intensive houses, public buildings, large public places, flammable and explosive places and places with strict fire-proof requirements, and can also be used as a fire-releasing isolation belt for construction to improve the fire-proof standard of the building.

Original feedway's feeder hopper does not have controlgear, and when the inside material of feeder hopper fell into the inside too much of feeder, can make the material pile up in the frame, and then lead to the lift resistance increase, the hopper operation was not smooth, can seriously make the hopper drop and warp, has reduced feedway's functionality like this, can not bring the facility for the staff.

SUMMERY OF THE UTILITY MODEL

To solve the problems set forth in the background art described above. The utility model provides a feeding device for producing inorganic active thermal insulation mortar, which has the characteristics of controlling the blanking amount of a feeding hopper and avoiding excessive materials in a functional feeding machine.

In order to achieve the purpose, the utility model provides the following technical scheme: a feeding device for producing inorganic active thermal insulation mortar comprises a feeder, wherein a conveying hopper is arranged below one end of the feeder, the conveying hopper is far away from one end of the feeder and is provided with a feeding hopper, the inside lower part of the feeding hopper is connected with a sealing plate through a control mechanism, the control mechanism comprises a top plate, a lifting frame, a connecting shaft, an extension plate, an eccentric block, a supporting frame and a connecting rod, the extension plate is arranged at one end of the inner side wall of the feeding hopper, the front surface of the extension plate is rotatably connected with the lifting frame, the top plate is arranged at two ends of the top of the lifting frame, the top of the top plate is connected with the bottom of the sealing plate, the connecting shaft is arranged at the middle position inside the lifting frame, the eccentric block is arranged below the connecting shaft and is connected with the feeding hopper through the supporting frame, and the connecting rod is arranged on the front surface of the eccentric block, the end of connecting rod runs through the front surface of feeder hopper, positioning mechanism is installed in the outside of connecting rod.

As the preferable technical scheme of the feeding device for producing the inorganic active thermal insulation mortar, the positioning mechanism comprises a positioning frame, a spring frame, a sliding rod, a sliding block, a rack and a rack, the positioning frame is installed on one side, close to the connecting rod, of the front surface of the feeding hopper, the sliding rod is installed inside the positioning frame, the spring frame and the sliding block are installed on the outer side wall of the sliding rod, the rack is installed on the front surface of the sliding block, the rack is connected to one side of the rack, and the rack is located on the outer side wall of the connecting rod.

According to the preferable technical scheme of the feeding device for producing the inorganic active thermal insulation mortar, the rear surface of the lifting frame is provided with the vertical plate, and the fixing plate at the end of the connecting shaft is positioned in the groove in the vertical plate.

As the preferable technical scheme of the feeding device for producing the inorganic active thermal insulation mortar, an operation panel is arranged on the front surface of the connecting rod.

As the preferable technical scheme of the feeding device for producing the inorganic active thermal insulation mortar, the closing plate is of an L-shaped structure.

As the preferable technical scheme of the feeding device for producing the inorganic active thermal insulation mortar, the eccentric block is in sliding connection with the connecting shaft.

Compared with the prior art, the utility model has the beneficial effects that: when the inside material of feeder is too much, can clockwise rotation operation board, make the closing plate up-move under the cooperation of the inside roof of control mechanism, crane, connecting axle, extension board, eccentric block, support frame and connecting rod, the in-process that moves up at the closing plate can reduce the open area between conveyer bucket and the feeder hopper, and then can avoid more materials to flow into the inside of feeder through the conveyer bucket through blockking of closing plate, avoid the inside more materials of piling up of feeder.

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 principles of the utility model and not to limit the utility model. In the drawings:

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

FIG. 2 is a schematic cross-sectional view of the feed hopper of FIG. 1 in accordance with the present invention;

FIG. 3 is an enlarged schematic view of the feed hopper of FIG. 2 in accordance with the present invention;

FIG. 4 is an enlarged schematic view of the control mechanism of FIG. 3 according to the present invention;

FIG. 5 is a schematic rear surface view of the control mechanism of FIG. 4 in accordance with the present invention;

FIG. 6 is an enlarged view of A of FIG. 1 according to the present invention;

FIG. 7 is an enlarged schematic view of the positioning mechanism of FIG. 6 according to the present invention;

in the figure: 1. a feeding machine; 2. a feed hopper; 3. a conveying hopper; 4. a closing plate; 5. a control mechanism; 51. a top plate; 52. a lifting frame; 53. a vertical plate; 54. a connecting shaft; 541. a fixing plate; 55. an extension plate; 56. an eccentric block; 57. a support frame; 58. a connecting rod; 581. an operation panel; 6. a positioning mechanism; 61. a positioning frame; 62. a spring holder; 63. a slide bar; 64. a slider; 65. a rack; 66. a rack.

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.

Examples

Referring to fig. 1-7, the present invention provides a technical solution: a feeding device for producing inorganic active thermal insulation mortar comprises a feeder 1, a conveying hopper 3 is installed below one end of the feeder 1, a feeding hopper 2 is installed at one end, far away from the feeder 1, of the conveying hopper 3, a closing plate 4 is connected to the lower portion inside the feeding hopper 2 through a control mechanism 5, the control mechanism 5 comprises a top plate 51, a lifting frame 52, a connecting shaft 54, an extending plate 55, an eccentric block 56, a supporting frame 57 and a connecting rod 58, the extending plate 55 is installed at one end of the inner side wall of the feeding hopper 2, the front surface of the extending plate 55 is rotatably connected with the lifting frame 52, the top plate 51 is installed at two ends of the top of the lifting frame 52, the top of the top plate 51 is connected with the bottom of the closing plate 4, the lifting frame 52 is provided with the eccentric block 54 at the middle position inside, the connecting shaft 54 is provided with an eccentric block 56, the eccentric block 56 is connected with the feeding hopper 2 through the supporting frame 57, and the connecting rod 58 is installed on the front surface of the eccentric block 56, the end of the connecting rod 58 penetrates the front surface of the feed hopper 2, and the positioning mechanism 6 is arranged on the outer side of the connecting rod 58.

In this embodiment, when the feeder 1 is TD-160 and a feeding device is needed, the material can be poured into the feeding hopper 2, and flows into the feeder 1 through the conveying hopper 3, and flows into the processing equipment through the feeder 1, so as to ensure the normal use of the feeding device,

in this embodiment, when the inside material of feeder 1 is too much, can make connecting rod 58 drive eccentric block 56 and rotate, can promote connecting axle 54 and up move when eccentric block 56 is rotatory, can drive crane 52 and stretch when connecting axle 54 up moves, then make crane 52 make closing plate 4 up move through roof 51, the in-process that up moves at closing plate 4 can reduce the open area between conveyer bucket 3 and the feeder hopper 2, and then can avoid more materials to flow into the inside of feeder 1 through conveyer bucket 3 through blockking of closing plate 4.

Specifically, the positioning mechanism 6 includes a positioning frame 61, a spring frame 62, a sliding rod 63, a sliding block 64, a rack 65 and a rack 66, the positioning frame 61 is installed on one side of the front surface of the feeding hopper 2 close to the connecting rod 58, the sliding rod 63 is installed inside the positioning frame 61, the spring frame 62 and the sliding block 64 are installed on the outer side wall of the sliding rod 63, the rack 65 is installed on the front surface of the sliding block 64, the rack 66 is connected to one side of the rack 65, and the rack 66 is located on the outer side wall of the connecting rod 58.

In this embodiment, when the connecting rod 58 needs to be fixed, the rack 65 can be contacted with the rack 66 on the outer side wall of the connecting rod 58 under the pushing of the spring holder 62, so that the connecting rod 58 can be prevented from rotating.

Specifically, the rear surface of the lifting frame 52 is provided with a vertical plate 53, and the fixing plate 541 at the end of the connecting shaft 54 is located in a groove inside the vertical plate 53.

In this embodiment, the fixing plate 541 on the rear surface of the connecting shaft 54 is embedded into the groove of the vertical plate 53, so that the connecting shaft 54 is prevented from shaking left and right, and the lifting frame 52 is ensured to ascend more stably.

Specifically, the front surface of the link 58 is mounted with an operation panel 581.

In this embodiment, the hand can be placed on the operation panel 581, and the link 58 can be rotated by rotating the operation panel 581, whereby the convenience of the link 58 can be increased.

Specifically, the closing plate 4 has an L-shaped structure.

In this embodiment, the closing plate 4 is made to have an L-shaped structure, so that the production material of the closing plate 4 can be reduced on the basis of ensuring the normal use of the closing plate 4.

In particular, the eccentric mass 56 is slidably coupled to the coupling shaft 54.

In this embodiment, the eccentric block 56 is slidably connected to the connecting shaft 54, so that the eccentric block 56 pushes the connecting shaft 54 more stably, and the jamming between the eccentric block and the connecting shaft is avoided.

The working principle and the using process of the utility model are as follows: after the feeding device is installed, when the feeding device needs to be used, materials can be poured into the feeding hopper 2 and flow into the feeding machine 1 through the conveying hopper 3, and flow into the processing equipment through the feeding machine 1, so that the normal use of the feeding device is ensured, when the materials in the feeding machine 1 are excessive, the operating disc 581 can be rotated clockwise, the connecting rod 58 can drive the eccentric block 56 to rotate through the operating disc 581, the connecting shaft 54 can be pushed to move upwards while the eccentric block 56 rotates, the lifting frame 52 can be driven to stretch while the connecting shaft 54 moves upwards, then the lifting frame 52 enables the closing plate 4 to move upwards through the top plate 51, the opening area between the conveying hopper 3 and the feeding hopper 2 can be reduced in the process that the closing plate 4 moves upwards, and further more materials can be prevented from flowing into the feeding machine 1 through the conveying hopper 3 due to the blocking of the closing plate 4, avoiding more material to pile up inside feeder 1.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the utility model. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides an inorganic active feedway for heat preservation mortar production, includes feeder (1), its characterized in that: the feeding device is characterized in that a conveying hopper (3) is installed below one end of the feeding machine (1), the conveying hopper (3) is far away from one end of the feeding machine (1) and is provided with a feeding hopper (2), the inside lower part of the feeding hopper (2) is connected with a sealing plate (4) through a control mechanism (5), the control mechanism (5) comprises a top plate (51), a lifting frame (52), a connecting shaft (54), an extending plate (55), an eccentric block (56), a supporting frame (57) and a connecting rod (58), the extending plate (55) is installed at one end of the inner side wall of the feeding hopper (2), the front surface of the extending plate (55) is rotatably connected with the lifting frame (52), the top plate (51) is installed at two ends of the top of the lifting frame (52), the top of the top plate (51) is connected with the bottom of the sealing plate (4), the connecting shaft (54) is installed at the middle position inside of the lifting frame (52), eccentric block (56) are installed to the below of connecting axle (54), eccentric block (56) with connect through support frame (57) between feeder hopper (2), the front surface mounting of eccentric block (56) has connecting rod (58), the end of connecting rod (58) runs through the front surface of feeder hopper (2), positioning mechanism (6) are installed in the outside of connecting rod (58).

2. The feeding device for producing the inorganic active thermal insulation mortar according to claim 1, which is characterized in that: positioning mechanism (6) are including positioning frame (61), spring frame (62), slide bar (63), slider (64), tooth frame (65) and rack (66), feeder hopper (2) front surface is close to positioning frame (61) are installed to one side of connecting rod (58), the internally mounted of positioning frame (61) has slide bar (63), spring frame (62) and slider (64) are installed to the lateral wall of slide bar (63), the front surface mounting of slider (64) has tooth frame (65), one side of tooth frame (65) is connected with rack (66), rack (66) are located the lateral wall of connecting rod (58).

3. The feeding device for producing the inorganic active thermal insulation mortar according to claim 1, which is characterized in that: the rear surface of the lifting frame (52) is provided with a vertical plate (53), and a fixing plate (541) at the end of the connecting shaft (54) is positioned in a groove in the vertical plate (53).

4. The feeding device for producing the inorganic active thermal insulation mortar according to claim 1, which is characterized in that: an operation panel (581) is mounted on the front surface of the connecting rod (58).

5. The feeding device for producing the inorganic active thermal insulation mortar according to claim 1, which is characterized in that: the closing plate (4) is of an L-shaped structure.

6. The feeding device for producing the inorganic active thermal insulation mortar according to claim 1, which is characterized in that: the eccentric block (56) is connected with the connecting shaft (54) in a sliding mode.

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