CN118270379A - Electric power material management device - Google Patents

Abstract

The invention discloses an electric power material management device which comprises a box body and vertical partition plates fixedly arranged in an inner cavity of the box body, wherein the box body is divided into a material bin and a dehumidification bin by the vertical partition plates, a plurality of water absorption layers are arranged in the dehumidification bin, and the water absorption layers are arranged in a plurality of ways and are folded and arranged in the vertical direction; an isolation component is arranged on the outer side of the water absorption layer; when the drive assembly upwards moves, can drive each layer that absorbs water from bottom to top and fold gradually, and the in-process of folding keeps apart each layer that absorbs water through the isolation component that sets up to be favorable to later stage to extrude the moisture in each layer that absorbs water better, compare and take a monoblock sponge layer to absorb water in traditional, at extruded in-process, because sponge layer intermediate position atress is less, thereby lead to the extrusion insufficient, make when using once more, the effect of absorbing water is poor, sponge layer in this scheme passes through the even pressfitting of clamp plate, the extrusion effect is better.

Description

A power material management device

Technical Field

The present invention relates to the technical field of power material management, and in particular to a power material management device.

Background technique

Electricity is an energy source that uses electrical energy as a driving force. In the process of using electricity, a large number of electric materials are needed, including electrical components and other items related to power facilities. In the storage process of electric materials, it is necessary to try to avoid the electric materials from getting damp, which will affect the service life of the electric materials.

Chinese patent CN216071356U discloses a material management device for an electric power enterprise, including a box body, a slot is provided through the side wall of the box body, and a circular sleeve barrel is fixedly connected to the inner wall of the slot, the opening of the circular sleeve barrel is arranged inside the box body, and one end thereof passes through the slot and extends outward, a fan is arranged inside the circular sleeve barrel, and the fan is connected to the inner wall of the circular sleeve barrel through a bracket, a rectangular hole is provided through the inner wall of the box body, and the rectangular hole is arranged on the lower side of the slot, a rectangular duct corresponding to the rectangular hole is fixedly connected to the side wall of the box body, one end of the rectangular duct away from the box body is connected to one end of the circular sleeve barrel passing through the slot, and two dehumidification mechanisms are arranged on the side wall of the rectangular duct. This scheme uses the effect that the wind force generated by the rotation of the fan enters the rectangular tube under the action of the wind guide plate, which is conducive to blowing out through multiple exhaust holes, thereby dehumidifying the inside of the box body and preventing humid air from causing damage to power materials.

The above device circulates the air flow in the box through a fan, and dehumidifies through the sponge during the circulation process. However, as the use time increases, the sponge gradually becomes saturated, and its ability to absorb moisture is greatly reduced. At this time, you can choose to replace it or squeeze it to squeeze out the moisture absorbed in the sponge and reuse it to extend its service life. However, when the sponge is thicker, the center of the sponge is subjected to less force during the squeezing process, which makes it difficult to discharge the moisture, affecting subsequent use.

Therefore, it is necessary to provide an electric power material management device to solve the above technical problems.

Summary of the invention

The purpose of the present invention is to provide an electric power material management device to solve the problem that the existing device proposed in the above background technology uses a sponge for dehumidification, but as the use time increases, the sponge gradually becomes saturated and its ability to absorb moisture is greatly reduced.

Based on the above ideas, the present invention provides the following technical solution: comprising a box body and a vertical partition fixedly arranged in the inner cavity of the box body, wherein the vertical partition divides the box body into a material bin and a dehumidification bin, wherein a water absorption layer is arranged in the dehumidification bin, wherein the water absorption layer is arranged in a plurality and folded in the vertical direction;

An isolation component is arranged on the outside of the water absorbing layer, and a driving component cooperating with the isolation component is arranged on the bottom of the dehumidification chamber. The driving component moves upward to drive each water absorbing layer to be gradually folded from bottom to top, and during the folding process, each water absorbing layer is isolated by the isolation component.

As a further solution of the present invention: a fan is arranged in the dehumidification bin, a fixing frame is fixedly connected to the top of one side of the vertical partition close to the dehumidification bin, the fan is installed in the fixing frame, a through air outlet is opened on the vertical partition at the fixing frame, and a through air inlet is opened at the bottom end of the vertical partition.

As a further scheme of the present invention: the isolation assembly includes a pressure plate fixedly arranged on the top and bottom of the water absorbing layer, a connecting strip is arranged between adjacent water absorbing layers, the top and bottom of the connecting strip are respectively hinged to the upper and lower pressure plates, the pressure plate located at the top of the water absorbing layer is fixedly arranged with a connecting plate, the connecting plate is arranged on the side of the pressure plate inclined downward, a slide groove is provided on the connecting plate, and a slide plate is slidably arranged in the slide groove, a traction rope is provided between the adjacent water absorbing layers, a slot is provided on the top surface of the pressure plate located at the top of the water absorbing layer, a card block is slidably arranged in the slot, and a second spring is provided in the slot at the bottom end of the card block, a limiting slot matching the card block is provided on the bottom surface of the slide plate, the bottom end of the traction rope is inserted into the pressure plate and extends into the slot to be fixed to the card block, the top end of the traction rope is fixed to the pressure plate, and a top plate is fixedly connected to the dehumidification bin in the box body, and the top plate is horizontally arranged and placed above multiple water absorbing layers.

As a further solution of the present invention: the driving assembly includes a turntable and a top block slidably arranged on the top of the turntable, a sliding rod is fixedly connected to the bottom surface of the turntable, and a fixed cylinder is provided on the outer sliding sleeve of the sliding rod, a plurality of spiral grooves arranged in a linear array are opened on the inner wall of the fixed cylinder, and the plurality of spiral grooves are staggered front and back on the inner wall of the fixed cylinder, a guide groove is opened on the inner wall of the fixed cylinder between the two spiral grooves, a limiting block is fixedly connected to the outer circumferential surface of the sliding rod, and the limiting block slidably cooperates with the spiral groove and the guide groove.

As a further solution of the present invention: a blind hole is opened on the top of the turntable, the top block is slidably arranged in the blind hole, and a third spring is arranged in the blind hole at the bottom end of the top block.

As a further solution of the present invention: baffles are arranged on both sides of the water absorbing layer, the baffles are fitted with the connecting plates, the outer sides of the two baffles are fixedly connected with guide columns, and the outer sides of the guide columns are sleeved with a first spring.

As a further solution of the present invention: the guide column on one side close to the vertical partition passes through the vertical partition and is slidably connected thereto, and the guide column on the other side passes through the side surface of the box and is slidably connected thereto.

As a further solution of the present invention: a pull rope is arranged between two adjacent water absorbing layers, and the pull rope passes through the water absorbing layers and is fixed to the pressing plate.

As a further solution of the present invention: the number of the sliding rods is set to two and they are symmetrically distributed about the water absorbing layer, a support plate is arranged between the two sliding rods, and the sliding rod passes through the support plate and rotates with the support plate.

As a further solution of the present invention: the bottom surface of the inner cavity of the slide groove is flush with the top surface of the pressure plate, convex strips are fixedly arranged on the front and rear sides of the bottom of the slide plate, and the inner bottom surface of the slide groove and the top surface of the pressure plate are provided with mutually connected strip grooves, and the convex strips are slidably arranged in the strip grooves.

Compared with the prior art, the beneficial effects of the present invention are as follows: a plurality of water-absorbing layers are provided and are folded in the vertical direction, an isolation component is provided on the outside of the water-absorbing layer, and a driving component matched with the isolation component is provided on the bottom of the dehumidification chamber. When the driving component moves upward, each water-absorbing layer can be driven to gradually fold from bottom to top, and in the process of folding, each water-absorbing layer is isolated by the isolation component, which is conducive to better squeezing out the water in each water-absorbing layer in the later stage. Compared with the traditional method of using a whole sponge layer to absorb water, during the extrusion process, the middle position of the sponge layer is subjected to less force, resulting in insufficient extrusion, so that the water absorption effect is poor when used again. The sponge layer in this scheme is evenly pressed by the pressing plate, and the extrusion effect is better.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described below in conjunction with the accompanying drawings and embodiments.

Fig. 1 is a schematic diagram of the overall structure of the present invention;

FIG2 is a schematic diagram of the internal structure of the box of the present invention;

FIG3 is a distribution diagram of the water absorbing layer and the connecting plate of the present invention;

FIG4 is a schematic diagram of the structure of the turntable and the pressing plate of the present invention;

FIG5 is a schematic diagram of the support plate and the slide bar structure of the present invention;

FIG6 is a structural diagram of the connection between the traction rope and the pressing plate of the present invention;

FIG7 is a schematic diagram of the structure of the connecting plate and the slide plate of the present invention;

FIG8 is a schematic diagram of the structure of the limit groove and the guide groove of the present invention;

FIG9 is a schematic diagram of the top block structure of the present invention;

10 is a schematic diagram of the structure of the card block and the limit groove of the present invention;

FIG11 is an enlarged structural schematic diagram of point A in FIG6 of the present invention;

FIG12 is an enlarged schematic diagram of the structure of B in FIG5 of the present invention;

FIG. 13 is a schematic diagram of the convex strip structure of the present invention.

In the figure: 1. box body; 2. guide column; 3. water storage box; 4. material bin; 5. exhaust port; 6. fixed frame; 7. dehumidification bin; 8. baffle; 9. connecting plate; 10. water absorption layer; 11. turntable; 12. drainage trough; 13. fixed cylinder; 14. water baffle; 15. air inlet; 16. top plate; 17. traction rope; 18. slide; 19. connecting strip; 20. pressure plate; 21. top block; 22. electric push rod; 23. first spring; 24. vertical partition; 25. slide bar; 26. support plate; 27. guide groove; 28. spiral groove; 29. block; 30. slide plate; 31. limit groove; 32. second spring; 33. third spring; 34. limit block; 35. pull rope; 36. convex strip; 37. strip groove.

Detailed ways

As shown in Figures 1-3, an electric power material management device includes a box body 1 and a vertical partition 24 fixedly arranged in the inner cavity of the box body 1. The box body 1 is divided into a material bin 4 and a dehumidification bin 7 by the vertical partition 24, and door panels are installed on the side of the box body 1 at the material bin 4 and the dehumidification bin 7 to facilitate the access and storage of materials in the box body 1. During the specific installation, multiple horizontal partitions can be installed at the material bin 4 to facilitate the classification and storage of materials.

A fan is arranged in the above-mentioned dehumidification bin 7. Specifically, a fixing frame 6 is fixedly connected to the top of the vertical partition 24 close to the dehumidification bin 7, and the fan is installed in the fixing frame 6. The front and rear ends of the fixing frame 6 are fixed to the inner wall of the box body 1. A through exhaust port 5 is opened on the vertical partition 24 at the fixing frame 6, and a through air inlet 15 is opened at the bottom end of the vertical partition 24. A water absorption layer 10 is arranged in the dehumidification bin 7.

In actual application, the electrical materials to be stored are stacked in the material bin 4, and air is continuously blown into the material bin 4 through the fan. As the air pressure in the material bin 4 increases, the air flows through the air inlet 15 to the dehumidification bin 7, and then flows back to the material bin 4 through the fan, thereby realizing the circulation of air flow in the box 1. In this process, when the air flow flows upward in the dehumidification bin 7, it will pass through the water absorption layer 10, and then it can absorb the moisture in the air flow, so as to keep the air flow in the box 1 dry, which is beneficial to the storage of electrical materials.

As shown in Figures 2-8 and 10-12, in actual use, the water absorbing layer 10 is provided in multiple numbers and folded in the vertical direction, an isolation component is provided on the outside of the water absorbing layer 10, and a driving component matching the isolation component is provided at the bottom of the dehumidification chamber 7. When the driving component moves upward, each water absorbing layer 10 can be driven to be gradually folded from bottom to top, and in the process of folding, each water absorbing layer 10 is isolated by the isolation component, which is conducive to better squeezing out the moisture in each water absorbing layer 10 in the later stage.

The above-mentioned isolation component includes a pressing plate 20 fixedly arranged on the top and bottom of the water-absorbing layer 10, and the pressing plate 20 is arranged in a "U" shape. A connecting strip 19 is arranged between two adjacent water-absorbing layers 10. The top and bottom of the connecting strip 19 are respectively hinged to the pressing plates 20 of the upper and lower layers. Specifically, the pressing plate 20 and the connecting strip 19 are hinged by hinges to form a folded structure of each water-absorbing layer 10. In actual application, the pressing plate 20 can be fixed to the water-absorbing layer 10 by bonding. In the dehumidified state, the water-absorbing layer 10 and the pressing plate 20 is in an inclined state, and the specific distribution is shown in Figure 3. A connecting plate 9 is arranged on the pressure plate 20 located on the top of the water-absorbing layer 10. The connecting plate 9 is arranged on the side of the pressure plate 20 that is inclined downward, and the connecting plate 9 is fixedly connected to the pressure plate 20. A slide groove 18 is opened on the connecting plate 9. The bottom surface of the inner cavity of the slide groove 18 is flush with the top surface of the pressure plate 20, and a slide plate 30 is slidably arranged in the slide groove 18. When the water-absorbing layer 10 drives the pressure plate 20 to deflect upward synchronously, the slide plate 30 will slide from the slide groove 18 and be clamped between two adjacent water-absorbing layers 10.

Furthermore, in order to evenly fold and distribute the multiple water-absorbing layers 10 in the dehumidification chamber 7, a traction rope 17 is provided between two adjacent water-absorbing layers 10, and a card slot is provided on the top surface of the pressure plate 20 located on the top of the water-absorbing layer 10, and a card block 29 is slidably provided in the card slot, and a second spring 32 is provided at the bottom end of the card block 29 in the card slot, and the two ends of the second spring 32 are respectively fixed to the inner bottom surface of the card slot and the bottom surface of the card block 29, and a limiting groove 31 matching with the card block 29 is provided on the bottom surface of the slide plate 30, and the bottom end of the traction rope 17 is inserted into the card slot. The pressure plate 20 extends into the slot and is fixed to the bottom surface of the block 29. The top of the traction rope 17 is fixed to the pressure plate 20 on the bottom surface of the upper water-absorbing layer 10, so as to promote uniform distribution of each water-absorbing layer 10. When multiple water-absorbing layers 10 are gradually folded and squeezed, the traction rope 17 loses the limit on the block 29. At this time, the block 29 bounces upward under the action of the second spring 32. When the slide plate 30 slides out of the slide groove 18, the cooperation between the block 29 and the limiting groove 31 is conducive to the stable placement of the slide plate 30 between the two adjacent water-absorbing layers 10.

Furthermore, a top plate 16 is arranged on the top of the topmost water-absorbing layer 10 , and the top plate 16 is arranged horizontally and fixedly connected to the box body 1 .

The above-mentioned driving assembly includes a turntable 11 and a top block 21 slidably arranged on the top of the turntable 11, a sliding rod 25 is fixedly connected to the bottom surface of the turntable 11, and the outer sliding sleeve of the sliding rod 25 is provided with a fixed cylinder 13, and the fixed cylinder 13 is fixed to the inner bottom surface of the box body 1, the number of the sliding rods 25 is set to two and is symmetrically distributed about the water-absorbing layer 10, a support plate 26 is arranged between the two sliding rods 25, the support plate 26 is placed at the bottom of the turntable 11, and the sliding rod 25 passes through the support plate 26 and rotates with it. During actual installation, the sliding rod 25 can be rotated with the support plate 26 through a bearing, or it can be rotated by the mutual engagement of an annular protrusion and an annular groove. Specifically, an annular protrusion protrudes outward on the outer circumferential surface of the sliding rod 25, and this annular protrusion is rotatably arranged in an annular groove opened on the support plate 26. The inner bottom surface of the box body 1 is located below the support plate 26 and is fixedly provided with an electric push rod 22, and the telescopic end of the electric push rod 22 is fixedly connected to the support plate 26.

Furthermore, a plurality of spiral grooves 28 arranged in a linear array are provided on the inner wall of the fixed cylinder 13, and the arc of the spiral grooves 28 projected on the horizontal plane is π/2. The plurality of spiral grooves 28 are staggered front and back on the inner wall of the fixed cylinder 13, and a guide groove 27 is provided on the inner wall of the fixed cylinder 13 between two spiral grooves 28, so that the front and rear two adjacent spiral grooves 28 are connected through the vertical guide groove 27, and the top end of the inner wall of the fixed cylinder 13 is a vertical guide groove 27, and a limit block 34 is fixedly connected to the outer circumferential surface of the slide rod 25, and the limit block 34 is slidably matched with the spiral groove 28 and the guide groove 27.

In actual use, the water-absorbing layer 10 can be made of materials with good water absorption such as sponge or pure cotton. After being used for a period of time, the water-absorbing layer 10 is gradually saturated. At this time, although the airflow in the box body 1 can circulate, it is difficult to keep the gas in the box body 1 dry through the saturated water-absorbing layer 10. Therefore, the support plate 26 can be driven to move upward by the electric push rod 22, and the support plate 26 can be used to drive the turntable 11 and the slide bar 25 to move upward. In the initial state, the top block 21 is located on the downwardly inclined side of the bottom water-absorbing layer 10. When the turntable 11 drives the top block 21 to move upward and contact with the pressure plate 20 at the bottom of the bottom water-absorbing layer 10, the water-absorbing layer 10 can be driven to deflect upward. Specifically, Figures 3-5 describe this. Since the top block 21 is in contact with the pressure plate 20, when the top block 21 continues to move upward, the bottom water-absorbing layer 10 gradually deflects from the downward tilt to the upward tilt, thereby making the bottom water-absorbing layer 10 connected thereto. When the sliding plate 30 slides to the top of the pressing plate 20, the block 29 will be engaged in the slot of the sliding plate 30, so that the sliding plate 30 is limited between the two adjacent water-absorbing layers 10 and will not be separated from them. In the above-mentioned movement process, the limiting block 34 always slides in the guide groove 27. After the sliding plate 30 slides out of the connecting plate 9 of the bottom layer, the limiting block 34 gradually slides from the guide groove 27 to the spiral groove 28. At this time, through the limiting between the limiting groove 31 and the spiral groove 28, the sliding bar 25 will rotate during the upward movement. The top block 21 is then moved 180°, thereby changing the direction of the top block 21 in the horizontal direction, and then the limit block 34 continues to move upward with the slide bar 25 and enters the guide groove 27 from the spiral groove 28. At this time, the top block 21 is aligned with the downwardly inclined end of the second-to-last water-absorbing layer 10. Therefore, when the turntable 11 drives the top block 21 to continue to move upward, the top block 21 can gradually drive the second-to-last water-absorbing layer 10 to deflect upward, thereby deflecting it from a downwardly inclined state to an upwardly inclined state. In this process, the slide plate 30 in this layer of connecting plate 9 will also slide downward and be placed between the two adjacent water-absorbing layers 10, that is, between the second-to-last and third-to-last water-absorbing layers 10. As the slide bar 25 continues to rise, and through the cooperation of the limit block 34, the guide groove 27 and the spiral groove 28, each water-absorbing layer 10 can be gradually folded and squeezed. When the limit block 34 slides to the top guide groove 27, multiple water-absorbing layers 10 After the folding and storage are completed and are all in a horizontal state, as the turntable 11 continues to move upward, the multiple water-absorbing layers 10 can be squeezed between the top plate 16 and the turntable 11, and the water in the water-absorbing layer 10 can be squeezed out. At this time, there are a pressing plate 20 and a sliding plate 30 between two adjacent water-absorbing layers 10, so that each water-absorbing layer 10 can be squeezed evenly, which is conducive to squeezing out the moisture in the water-absorbing layer 10. Compared with the traditional method of taking a whole sponge layer to absorb water, during the squeezing process, the force in the middle position of the sponge layer is small, resulting in insufficient squeezing, so that the water absorption effect is poor when it is used again. The sponge layer in this solution is evenly pressed by the pressing plate 20, and the squeezing effect is better. In actual use, in order to avoid interference between the two adjacent connecting plates 9 when the water-absorbing layer 10 is folded upward, the width of the connecting plate 9 can be made smaller than the width of the water-absorbing layer 10, so as to keep each water-absorbing layer 10 stable and folded upward.

When the extrusion is completed, the support plate 26 is driven downward by the electric push rod 22, so that the multiple water absorbing layers 10 can be unfolded again. At this time, the traction rope 17 can limit the position of each water absorbing layer 10 to make it evenly distributed, and when the traction rope 17 is straightened, the traction force of the traction rope 17 on the block 29 makes the block 29 overcome the force of the second spring 32 and be stored in the slot. At this time, the block 29 loses the limit on the slide plate 30, and the multiple water absorbing layers 10 are also in the initial state of tilting downward, so that the slide plate 30 slides into the connecting plate 9 again under the action of its own gravity, which can avoid affecting the water absorbing layer 10 and allow the airflow to flow upward smoothly through the water absorbing layer 10.

As shown in Figure 13, in order for the slide plate 30 to be able to return smoothly to the slide groove 18, in actual use, convex strips 36 can be fixedly set on the front and rear sides of the bottom of the slide plate 30, and mutually connected strip grooves 37 are opened on the bottom surface of the slide groove 18 and the top surface of the pressure plate 20, so that the convex strips 36 are slidably set in the strip grooves 37, and the cross-sectional shapes of the convex strips 36 and the strip grooves 37 are both set to T-shaped, so as to prevent the slide plate 30 from being separated from the pressure plate 20 or the connecting plate 9.

As shown in FIG9 , a blind hole is provided at the top edge of the turntable 11 , the top block 21 is slidably disposed in the blind hole, and a third spring 33 is disposed in the blind hole, so that both ends of the third spring 33 are respectively fixed to the top block 21 and the bottom surface of the blind hole.

During use, when the turntable 11 squeezes the multiple water-absorbing layers 10 to the top plate 16, since the limit block 34 slides in the guide groove 27, the slide rod 25 will drive the top block 21 to continue to move vertically upward, so that the top block 21 is squeezed and stored in the blind hole. At this time, the top of the turntable 11 is a plane, which is conducive to fitting with the pressure plate 20, thereby better squeezing the multiple water-absorbing layers 10.

As shown in Figures 1-2, a water baffle 14 is fixedly installed on one side of the vertical partition 24 close to the dehumidification bin 7, and the water baffle 14 is arranged at the air inlet 15, which is beneficial to prevent the squeezed water from flowing into the material bin 4 through the air inlet 15, and a drainage groove 12 is opened on the side of the box body 1 located in the dehumidification bin 7, and a water storage box 3 is fixedly connected to the outside of the box body 1, and the water storage box 3 is communicated with the drainage groove 12 to store the squeezed water.

As shown in Figure 2, baffles 8 are provided on both sides of the water-absorbing layer 10, and guide columns 2 are fixedly connected to the outer sides of the two baffles 8. The guide column 2 on the left side passes through the vertical partition 24 and is slidably connected thereto, and the guide column 2 on the right side passes through the side of the box body 1 and is slidably connected thereto, and a first spring 23 is sleeved on the outer side of the guide column 2, and the first spring 23 is respectively arranged between the baffle 8 and the vertical partition 24, and between the baffle 8 and the box body 1.

The side of the baffle 8 is in contact with the connecting plate 9, and the top of the left baffle 8 is in contact with the bottom of the fixed frame 6, and the top of the right baffle 8 is in contact with the top wall of the box body 1. When the fan is working, the airflow squeezed into the dehumidification chamber 7 can flow upward from between the two baffles 8, so that the airflow passes through the water absorption layer 10 for dehumidification, and when the water absorption layer 10 and the connecting plate 9 are folded, the baffle 8 can be driven to slide to both sides to avoid interference.

As shown in FIG. 3 , in actual use, a pull rope 35 may be provided between two adjacent water absorbing layers 10 . The pull rope 35 passes through the water absorbing layer 10 and is fixed to the pressing plate 20 . This structure can prevent the pressing plate 20 from exerting a large pulling force on the water absorbing layer 10 , thereby damaging the water absorbing layer 10 .

In addition, a humidity sensor can be installed in the box 1 to detect the air inside the box 1 in real time. When the humidity sensor detects that the air humidity exceeds a preset value, the analog signal is sent to a controller, such as a single-chip microcomputer or a PLC. After being processed by the controller, the analog signal is transmitted to the control terminal to remind the staff, so that the electric push rod 22 can be started in time to perform the operation, which is conducive to better monitoring and management of materials.

Claims (10)

1. The utility model provides an electric power material management device, includes the box and the fixed perpendicular baffle that sets up in the box inner chamber, perpendicular baffle divide into material storehouse and dehumidification storehouse with the box, its characterized in that: the dehumidifying bin is internally provided with a plurality of water absorbing layers which are arranged in a folding way in the vertical direction;

The outside of layer that absorbs water is provided with isolation component, and the inside bottom of dehumidification storehouse is provided with and keeps apart subassembly matched with drive assembly, upwards moves through drive assembly and drives each layer that absorbs water from bottom to top and fold gradually, and the folding in-process keeps apart each layer that absorbs water through the isolation component that sets up.

2. The electrical power asset management device of claim 1, wherein: the air conditioner is characterized in that a fan is arranged in the dehumidification bin, a fixed frame is fixedly connected to the top end of one side, close to the dehumidification bin, of the vertical partition plate, the fan is arranged in the fixed frame, a penetrating air outlet is formed in the position, located at the fixed frame, of the vertical partition plate, and a penetrating air inlet is formed in the bottom end of the vertical partition plate.

3. The electrical power asset management device of claim 1, wherein: the utility model provides a moisture absorption layer, including the isolation component, the isolation component is including fixed the clamp plate that sets up in moisture absorption layer top and bottom, be provided with the connecting strip between the adjacent two moisture absorption layers, the top and the bottom of connecting strip are articulated mutually with the clamp plate of upper and lower two-layer respectively, are located fixed being provided with the connecting plate on the clamp plate at moisture absorption layer top, the connecting plate sets up in the decurrent one side of clamp plate slope, the spout has been seted up on the connecting plate, and the sliding is provided with the slide in the spout, is provided with the haulage rope between the adjacent two moisture absorption layers, and the draw-in groove has been seted up to the clamp plate top surface that is located moisture absorption layer top, the sliding is provided with the fixture block in the draw-in groove, and is located the fixture block bottom and be provided with the second spring, offered on the bottom of slide with fixture block matched with spacing groove, the bottom of haulage rope inserts the clamp plate and extends to the clamp block in and is fixed mutually, the top and the clamp plate are fixed, be located dehumidification storehouse department fixedly connected with roof in the box, the roof level sets up and arranges in the top of a plurality of moisture absorption layers.

4. A power material management apparatus according to claim 3, wherein: the driving assembly comprises a rotary table and a top block arranged at the top of the rotary table in a sliding manner, a sliding rod is fixedly connected to the bottom surface of the rotary table, a fixed cylinder is arranged on the outer side sliding sleeve of the sliding rod, a plurality of spiral grooves which are arranged in a linear array are formed in the inner wall of the fixed cylinder, the spiral grooves are distributed on the inner wall of the fixed cylinder in a staggered manner, a guide groove is formed in the inner wall of the fixed cylinder between the two spiral grooves, and a limiting block is fixedly connected to the outer peripheral surface of the sliding rod and is in sliding fit with the spiral grooves and the guide groove.

5. The electrical power asset management device of claim 4, wherein: the blind hole has been seted up at the top of carousel, the kicking block slides and sets up in the blind hole, and is located the kicking block bottom in the blind hole and be provided with the third spring.

6. A power material management apparatus according to claim 3, wherein: the water absorption layer all is provided with the baffle in both sides, and the baffle is laminated mutually with the connecting plate, and the equal fixedly connected with guide post of lateral surface of two baffles, the outside cover of guide post is equipped with first spring.

7. The electrical power asset management device of claim 6, wherein: the guide post near one side of the vertical partition board penetrates through the vertical partition board and is in sliding connection with the vertical partition board, and the guide post on the other side penetrates through the side face of the box body and is in sliding connection with the box body.

8. A power material management apparatus according to claim 3, wherein: a pull rope is arranged between two adjacent water absorption layers, and the pull rope penetrates through the water absorption layers and is fixed with the pressing plate.

9. The electrical power asset management device of claim 4, wherein: the number of the sliding rods is two, the sliding rods are symmetrically distributed on the water absorption layer, a supporting plate is arranged between the two sliding rods, and the sliding rods penetrate through the supporting plate and are in running fit with the supporting plate.

10. A power material management apparatus according to claim 3, wherein: the inner chamber bottom surface of spout is parallel and level mutually with the top surface of clamp plate, both sides are all fixed around the slide bottom are provided with the sand grip, the bar groove of intercommunication each other has all been seted up on the top surface of the inside bottom surface of spout and clamp plate, the sand grip slides and sets up in the bar inslot.