CN210762650U

CN210762650U - Automatic powder lifting device

Info

Publication number: CN210762650U
Application number: CN201921797161.2U
Authority: CN
Inventors: 杜正银; 樊先荣
Original assignee: Dongguan Xinrong Tianli Technology Industrial Co ltd
Current assignee: Dongguan Xinrong Tianli Technology Industrial Co ltd
Priority date: 2019-10-24
Filing date: 2019-10-24
Publication date: 2020-06-16
Anticipated expiration: 2029-10-24

Abstract

The utility model discloses an automatic powder hoisting device, include: the powder conveying device comprises a material conveying pipeline, a powder conveying pipeline and a powder conveying device, wherein the material conveying pipeline is used for conveying powder, and comprises a feeding hole and a discharging hole which are arranged on the side wall of the material conveying pipeline; the conveying component penetrates into the first end of the conveying pipeline and penetrates out of the second end of the conveying pipeline to form a closed loop; the powder carrier plate is used for loading powder, and the powder carrier plate is fixedly arranged on the conveying assembly; the bottom connects the feed bin, the first end and the second end of conveying pipeline all connect the feed bin is connect to the bottom, make conveying pipeline with the bottom connect the feed bin to form enclosed construction. The utility model discloses automatic powder hoisting device simple structure, convenient to use has reduced the recruitment cost, has improved conveying efficiency, and because conveying pipeline connects the material storehouse with the bottom to form enclosed construction, prevents effectively that the powder from flying upward, reduces environmental pollution.

Description

Automatic powder lifting device

Technical Field

The utility model belongs to the mechanical equipment field, concretely relates to automatic powder hoisting device.

Background

In the process of factory production, often need transport or promote the powder, current many mills transport or promote the operation to the powder, are accomplished by manual work usually, and efficiency is lower, and in the transportation or promote the operation, cause the dust to fly upward easily, cause environmental pollution.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic powder hoisting device is same as solving the powder lifting efficiency low, flies the problem of powder easily.

An automatic powder lifting device comprising:

the powder conveying device comprises a material conveying pipeline, a powder conveying pipeline and a powder conveying device, wherein the material conveying pipeline is used for conveying powder, and comprises a feeding hole and a discharging hole which are arranged on the side wall of the material conveying pipeline;

the conveying component penetrates into the first end of the conveying pipeline and penetrates out of the second end of the conveying pipeline to form a closed loop;

the powder carrier plate is used for loading powder, and the powder carrier plate is fixedly arranged on the conveying assembly;

the bottom connects the feed bin, the first end and the second end of conveying pipeline all connect the feed bin is connect to the bottom, make conveying pipeline with the bottom connect the feed bin to form enclosed construction.

Further, the conveying pipeline includes:

a first section, a second section, and a third section;

the first section and the third section are both vertical pipelines, the second section is a horizontal pipeline, the first section, the second section and the third section are sequentially connected, the feed port and the discharge port are arranged on the outer side wall of the first section, and the distance between the discharge port and the bottom material receiving bin is higher than that between the feed port and the bottom material receiving bin.

Further, when the powder carrier plate moves to the first section, the upper surface of the powder carrier plate faces upwards; when the powder carrier plate moves to the second section, the powder carrier plate is in a vertical state; when the powder carrier plate moves to the third section, the upper surface of the powder carrier plate faces downwards.

Furthermore, a first opening is formed in the inner side wall of the second section, a first bulk material collecting bin is connected below the first opening, and the first bulk material collecting bin is used for collecting the residual powder on the powder carrier plate when the powder carrier plate rotates to the second section.

Furthermore, a second opening is formed in the middle section of the third section, a second bulk material collecting bin is connected to the second opening and used for collecting the residual powder on the powder carrier plate when the powder carrier plate rotates to the third section, one end of the second bulk material collecting bin is connected with the second opening, and the other end of the second bulk material collecting bin is communicated with the first section.

Furthermore, the discharge ports comprise a first discharge port and a second discharge port, one end of the first discharge port is connected with the outer side wall of the first section, and the other end of the first discharge port is connected with a material bag; one end of the second discharge port is connected with the outer side wall of the first section and the first bulk material collecting bin, and the other end of the second discharge port is connected with a material bag.

Further, the powder carriers are arranged on the conveyor assembly at equal distance intervals, so that each powder carrier transports an equal amount of powder.

Furthermore, the powder carrier plate is abutted against the material conveying pipeline.

Furthermore, the conveying assembly is driven by a speed reduction motor to rotate so as to keep the conveying assembly at a constant speed in the rotating process.

Further, the conveying assembly is a conveying chain.

The utility model discloses automatic powder hoisting device simple structure, convenient to use has reduced the recruitment cost, has improved conveying efficiency, and because conveying pipeline connects the material storehouse with the bottom to form enclosed construction, prevents effectively that the powder from flying upward, reduces environmental pollution.

Drawings

Fig. 1 is a schematic structural view of the automatic powder lifting device of the present invention.

Wherein, 1, a material conveying pipeline; 101. a feed inlet; 102. a discharge port; 1021. a first discharge port; 1022. a second discharge port; 103. a first stage; 104. a second stage; 1041. a first opening; 105. a third stage; 1051. a second opening; 106. a first end; 107. a second end; 2. a transfer assembly; 3. a powder material support plate; 4. the bottom is connected with a stock bin; 5. a first bulk material collection bin; 6. and a second bulk material collecting bin.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

It should be noted that the description relating to "first", "second", etc. in the present invention is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

As shown in fig. 1, the utility model discloses an automatic powder hoisting device, include:

the powder conveying device comprises a material conveying pipeline 1, wherein the material conveying pipeline 1 is used for conveying powder, the material conveying pipeline 1 comprises a feeding hole 101 and a discharging hole 102, and the feeding hole 101 and the discharging hole 102 are arranged on the side wall of the material conveying pipeline 1; after the powder enters from the feeding hole 101, the powder passes through the material conveying pipeline 1 and is output from the discharging hole 102, the whole transportation process is carried out in a closed environment, and the powder pollution caused by air contact in the transportation process can be effectively prevented.

The conveying component 2 penetrates into the first end 106 of the conveying pipeline 1 and penetrates out of the second end 107 of the conveying pipeline 1 to form a closed loop;

at least one powder carrier plate 3, wherein the powder carrier plate 3 is used for loading powder, and at least one powder carrier plate 3 is fixedly arranged on the conveying assembly 2; in an embodiment, a plurality of powder support plates 3 may be provided, when there is only one powder support plate 3, the amount of the transported powder is limited, when there are a plurality of powder support plates 3, the amount of the loaded powder can be effectively increased, and the powder transport rate can be increased, the shape of the powder support plate 3 is determined according to the shape of the material delivery pipeline 1, for example, when the material delivery pipeline 1 is a circular pipe, the powder support plate 3 is circular, and when the material delivery pipeline 1 is a square pipe, the powder support plate 3 is square.

The material conveying device comprises a bottom material receiving bin 4, wherein a first end 106 and a second end 107 of the material conveying pipeline 1 are connected with the bottom material receiving bin 4, so that the material conveying pipeline 1 and the bottom material receiving bin 4 form a closed structure. The bottom material receiving bin 4 is used for storing leaked powder when the powder carrier plate 3 is used for lifting the powder, the bottom material receiving bin 4 and the material conveying pipeline 1 form a closed structure, and even if the powder is stored in the bottom material receiving bin 4, the powder cannot deteriorate due to exposure to air.

In one embodiment, the delivery conduit 1 comprises:

a first segment 103, a second segment 104, and a third segment 105;

the first section 103 and the third section 105 are both vertical pipelines, the second section 104 is a horizontal pipeline, the first section 103, the second section 104 and the third section 105 are sequentially connected, the feed port 101 and the discharge port 102 are both arranged on the outer side wall of the first section 103, and the position of the discharge port 102, which is far away from the bottom receiving bin 4, is higher than the position of the feed port 101, which is far away from the bottom receiving bin 4. The powder enters from the feeding hole 101 and is output from the discharging hole 102, and the lifting operation of the powder is completed. The feed inlet 101 is funnel-shaped, so that powder can enter conveniently, and the tail end of the funnel-shaped is communicated with the bottom of the first section 103.

When the powder carrier plate 3 moves to the first section 103, the upper surface of the powder carrier plate 3 faces upwards; when the powder carrier plate 3 moves to the second section 104, the powder carrier plate 3 is in a vertical state; when the powder carrier plate 3 moves to the third section 105, the upper surface of the powder carrier plate 3 faces downwards. Specifically, when the powder carrier plate 3 moves to the first section 103, the powder carrier plate 3 is loaded with powder, after the powder carrier plate 3 reaches the discharge port 102 to unload the powder, a residual part of the powder may still remain on the powder carrier plate 3, and after the powder carrier plate 3 continues to move to the second section 104, the powder carrier plate 3 becomes in a vertical state, so that the residual part of the powder on the powder carrier plate 3 can continue to be unloaded, after the powder carrier plate 3 passes through the second section 104, a small part of the powder may still remain on the powder carrier plate 3, and after the powder carrier plate continues to move to the third section 105, the upper surface of the powder carrier plate 3 faces downward, so that the residual part of the powder can be completely unloaded, thereby avoiding the accumulation of the.

A first opening 1041 is formed in the inner side wall of the second section 104, a first bulk material collecting bin 5 is connected below the first opening 1041, and the first bulk material collecting bin 5 is used for collecting the powder remained on the powder carrier plate 3 when the powder carrier plate 3 rotates to the second section 104. When the powder carrier plate 3 moves to the second section 104 and the powder carrier plate 3 becomes vertical, the residual powder enters the first bulk material collecting bin 5 through the first opening 1041.

A second opening 1051 is formed in the middle section of the third section 105, the second opening 1051 is connected with a second bulk material collecting bin 6, the second bulk material collecting bin 6 is used for collecting the residual powder on the powder carrier plate 3 when the powder carrier plate 3 rotates to the third section 105, one end of the second bulk material collecting bin 6 is connected with the second opening 1051, and the other end of the second bulk material collecting bin 6 is communicated with the first section 103. When the powder carrier plate 3 moves to the third section 105, and the upper surface of the powder carrier plate 3 faces downward, a small part of the remaining powder enters the second bulk material collecting bin 6 through the second opening 1051, and the other end of the second bulk material collecting bin 6 is communicated with the material conveying pipeline 1, so that a small part of the remaining powder on the powder carrier plate 3 can enter the material conveying pipeline 1, and further the powder is output from the material outlet 102.

The discharge port 102 comprises a first discharge port 1021 and a second discharge port 1022, wherein one end of the first discharge port 1021 is connected with the outer side wall of the first section 103, and the other end of the first discharge port 1021 is connected with a material bag (not shown in the figure); one end of the second discharge port 1022 is connected to the outer side wall of the first section 103 and the first bulk collecting bin 5, and the other end of the second discharge port 1022 is connected to a bag. The first discharge port 1021 and the second discharge port 1022 are both inclined downwards to ensure the speed of the powder coming out from the discharge port 102, and one end of the second discharge port 1022 is connected with the outer side wall of the first section 103 and the first bulk material collecting bin 5, so that the powder in the first bulk material collecting bin 5 can enter the material conveying pipeline 1 again. In one embodiment, the powder carrier plates 3 are arranged on the conveying assembly 2 at equal intervals, so that each powder carrier plate 3 transports an equal amount of powder, and the weight error of the powder transported by each powder carrier plate 3 is not too large, thereby facilitating quantitative powder access.

The powder carrier plate 3 is abutted against the material conveying pipeline 1, so that after the powder carrier plate 3 is loaded with powder, the powder is prevented from falling into the material conveying pipeline 1 from the powder carrier plate 3 in the first section 103 of the material conveying pipeline 1 during powder conveying.

The conveying assembly 2 is driven to rotate by a speed reducing motor (not shown in the figure), so that the conveying assembly 2 keeps a constant speed in the rotating process. In one embodiment, the control assembly controls the rotational speed of the conveyor assembly 2 by controlling a gear motor.

The conveyor assembly 2 is a conveyor chain. In one embodiment, the conveying component 2 is a conveying chain, and in other embodiments, the conveying component 2 may be a conveying belt or the like, and the present solution is not limited herein.

The utility model discloses automatic powder hoisting device promotes the process of powder and does: after the powder enters from the feeding port 101 and is loaded on the powder carrier plate 3, the powder carrier plate 3 is loaded with the powder, and moves upwards under the driving of the conveying assembly 2, and reaches the second discharging port 1022, a part of the powder firstly passes through the second discharging port 1022 and enters the loading bag, the rest of the powder continues to move upwards under the driving of the conveying assembly 2, and reaches the first discharging port 1021, and enters the loading bag through the first discharging port 1021, at this time, most of the powder is lifted, the powder carrier plate 3 continues to move under the driving of the conveying assembly 2, when moving to the second section 104, the powder carrier plate 3 becomes vertical, a small part of the powder possibly still remains on the powder carrier plate 3, the remaining small part of the powder enters the conveying pipeline 1 through the first bulk material bin, and then enters the loading bag through the second discharging port, when moving to the third section 105, the upper surface of the powder 3 faces downwards, the small part of the bulk material 1022 enters the second collecting bin 6 through the second opening 1051, the other end of the second bulk material collecting bin 6 is communicated with the material conveying pipeline 1, so that a small part of the powder left on the powder carrier plate 3 can enter the material conveying pipeline 1, and further the powder is output from the material outlet 102.

The utility model discloses automatic powder hoisting device simple structure, convenient to use has reduced the recruitment cost, has improved conveying efficiency, and because conveying pipeline 1 meets feed bin 4 with the bottom and forms the enclosed construction, prevents effectively that the powder from flying upward, reduces environmental pollution.

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 modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. 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

1. An automatic powder lifting device, characterized by comprising:

2. The automatic powder lifting device of claim 1, wherein said delivery conduit comprises:

a first section, a second section, and a third section;

3. The automatic powder lifting device of claim 2, wherein the upper surface of said powder carrier plate faces upward when said powder carrier plate moves to said first section; when the powder carrier plate moves to the second section, the powder carrier plate is in a vertical state; when the powder carrier plate moves to the third section, the upper surface of the powder carrier plate faces downwards.

4. The automatic powder lifting device of claim 3, wherein the inner sidewall of the second section is provided with a first opening, a first bulk material collecting bin is connected below the first opening, and the first bulk material collecting bin is used for collecting the powder remained on the powder carrier plate when the powder carrier plate rotates to the second section.

5. The automatic powder lifting device of claim 4, wherein a second opening is formed in the middle section of the third section, the second opening is connected with a second bulk material collecting bin, the second bulk material collecting bin is used for collecting powder remained on the powder carrier plate when the powder carrier plate rotates to the third section, one end of the second bulk material collecting bin is connected with the second opening, and the other end of the second bulk material collecting bin is communicated with the first section.

6. The automatic powder lifting device of claim 5, wherein the discharge port comprises a first discharge port and a second discharge port, one end of the first discharge port is connected with the outer side wall of the first section, and the other end of the first discharge port is connected with a bag; one end of the second discharge port is connected with the outer side wall of the first section and the first bulk material collecting bin, and the other end of the second discharge port is connected with a material bag.

7. The automatic powder lifting device of claim 6, wherein said powder carriers are spaced apart at equal distances on said conveyor assembly such that each of said powder carriers transports an equal amount of powder.

8. The automatic powder lifting device of claim 7, wherein said powder carrier plate abuts said delivery conduit.

9. The automatic powder lifting device of claim 8, wherein the conveyor assembly is rotated by a speed reduction motor to maintain the conveyor assembly at a constant speed during rotation.

10. The automatic powder lifting apparatus of claim 9, wherein the conveyor assembly is a conveyor chain.