Intelligent electric meter storage automatic stereoscopic warehouse

By employing a combination of multi-stage telescopic panels and mobile suction devices in the automated three-dimensional warehouse for smart meter storage, the problems of dust dispersion and incomplete removal of the thermal boundary layer caused by the wind impact of traditional air curtains have been solved, achieving efficient and pollution-free meter storage.

CN121626592BActive Publication Date: 2026-06-19JIANGSU JUXIANGRUI ELECTRICAL EQUIPMENT TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
JIANGSU JUXIANGRUI ELECTRICAL EQUIPMENT TECHNOLOGY CO LTD
Filing Date
2025-12-11
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Traditional air curtains have strong wind impacts, causing dust to be scattered during smart meter storage, making it difficult to gently and thoroughly remove the thermal boundary layer and affecting storage efficiency.

Method used

Design an automated three-dimensional warehouse for smart meter storage, which adopts a multi-stage telescopic plate and a mobile suction device. Through the combination structure of through groove, bottom cavity groove and ventilation hole groove, it can achieve low-speed and gentle removal of thermal boundary layer, and perform secondary removal through the suction force of the top air duct and the hollow interior of the storage rack.

Benefits of technology

It effectively improves the transportation and storage efficiency of smart meters, avoids secondary dust pollution, ensures the dryness of the meter surface, and is suitable for normal temperature dry storage environment of smart meters.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention belongs to the field of material handling technology, specifically an automated three-dimensional warehouse for smart meter storage, including multiple storage racks and a stacking and transporting device movably installed between two storage racks. Positioning boxes are installed on the sides of the storage racks, and turnover boxes are positioned inside the positioning boxes. A bottom cavity groove is formed at the bottom of the turnover box, and a through groove is formed at the bottom of the bottom cavity groove. Multiple ventilation holes are formed above the bottom cavity groove. The contraction and retraction of multi-stage telescopic plates moves the turnover box above a U-shaped plate. After movement, the suction position of the mobile suction device overlaps with the through groove, and the suction force acts on the interior of the turnover box through the through groove, bottom cavity groove, and multiple ventilation holes. This can gently and slowly peel off any thermal boundary layer that may exist on the surface of the meter body, and this process is incorporated into the transportation of the turnover box by the stacking and transporting device.
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Description

Technical Field

[0001] This invention belongs to the field of goods handling, specifically an automated three-dimensional warehouse for smart meter storage. Background Technology

[0002] To upgrade single-meter management to whole-box management, and to complete the functions of warehousing, handling, picking and outbound in one go, multiple calibrated smart meters need to be placed inside the turnover box, and then placed on the shelf in an orderly manner through automated stacking and conveying, thereby completing the transportation and three-dimensional warehousing of smart meters.

[0003] A patent document with announcement number CN222664829U discloses a turnover box handling device, including a gantry frame, a conveyor belt, a clamp, a transfer mechanism, and a drive mechanism. The conveyor belt is used to transport turnover boxes to be handled, the clamp is used to clamp turnover boxes on the conveyor belt, the transfer mechanism is used to receive turnover boxes clamped by the stacking clamp, and the drive mechanism is connected to and drives the clamp to move up and down, left and right, and forward and backward.

[0004] In traditional technology, when storing multiple calibrated smart meters, the first step is to use an air curtain to remove the heat layer and dehumidify and prevent dust. This is to prevent the formation of a thermal boundary layer around the meter body due to the surface temperature after calibration, which would hinder the storage of smart meters at room temperature and dryness. However, the air curtain in traditional technology has a strong airflow force, which can easily cause dust to be stirred up. It is also difficult to gently and continuously remove the heat layer and dehumidify and prevent dust from multiple smart meters inside the turnover box. This may result in multiple smart meters in the automated storage and retrieval system requiring secondary processing.

[0005] Therefore, the present invention provides an automated three-dimensional warehouse for smart meter storage to solve the problems mentioned in the background art. Summary of the Invention

[0006] The technical solution adopted by the present invention to solve its technical problem is as follows: The present invention provides an automated three-dimensional warehouse for smart meter storage, comprising multiple storage racks and a stacking and transport device movably installed between two of the storage racks. A positioning box is installed on the side of the storage rack, and a turnover box is positioned inside the positioning box. Multiple electric meter bodies are placed inside the turnover box. A top air duct is installed above the storage rack. The interior of the storage rack is hollow, and the hollow interior of the storage rack is connected to the air vent of the top air duct.

[0007] The stacking and transporting device includes a transfer device, which includes a U-shaped plate and component slots opened inside both sides of the U-shaped plate. The U-shaped plate is equipped with multi-stage telescopic plates, and the component slots are equipped with mobile suction devices.

[0008] The bottom of the turnover box is provided with a bottom cavity groove, the bottom of the bottom cavity groove is provided with a through groove, and the top of the bottom cavity groove is provided with multiple ventilation holes.

[0009] The storage rack has racks installed on both sides. The turnover box is placed on four adjacent racks at the same horizontal level. The racks have connecting grooves inside, and the connecting grooves are connected to the hollow interior of the storage rack.

[0010] Preferably, the stacking and transporting device includes two guide rails fixedly installed at the top and bottom of the warehouse, a transport frame movably installed between the two guide rails, and the transfer device installed on one side of the transport frame.

[0011] Preferably, the multi-stage telescopic plate transports the turnover box inside the positioning box to the U-shaped plate through multi-stage telescopic movement. The width of the multi-stage telescopic plate is smaller than the width of the turnover box, and the width of the turnover box is smaller than the distance between the inner walls on both sides of the U-shaped plate.

[0012] Preferably, the mobile suction device includes a fixed frame fixedly installed inside the component groove, a fixed motor fixedly installed inside the fixed frame, a telescopic rod installed on one side of the fixed motor, and a movable block movably installed inside the fixed frame, the side of the movable block being connected to the end of the telescopic rod.

[0013] Preferably, the movable block has a suction groove inside, and an air pipe is installed below the suction groove. The other end of the air pipe is connected to an external suction device.

[0014] Preferably, when the telescopic rod is fully extended, the suction groove is connected to the corresponding through groove, and the length and width of the suction groove, through groove, and connecting groove are all equal.

[0015] Preferably, the interior of the turnover box is equipped with ribs, which are used to regulate the placement of multiple meter bodies, and multiple hollow strips are installed at the bottom of the turnover box.

[0016] Preferably, the top of the hollow strip is at the same horizontal level as the top of the ventilation slot, the bottom of the hollow strip is connected to the outside, and the hollow interior of the hollow strip is not connected to the bottom cavity slot.

[0017] Preferably, the hollow interior of the storage rack includes a ventilation slot formed inside the storage rack and a plurality of transverse slots formed on the side of the ventilation slot, wherein the plurality of transverse slots are connected to the corresponding connecting slots.

[0018] Preferably, the storage rack has a V-shaped groove on its inner top, which is connected to the ventilation groove and the interior of the top air duct.

[0019] The beneficial effects of this invention are as follows:

[0020] 1. The automated three-dimensional warehouse for smart meter storage described in this invention uses the contraction of multi-stage telescopic plates to move a turnover box above and inside a U-shaped plate. At this time, multiple through slots at the four corners of the bottom of the turnover box are located in the gap between the inner walls of the multi-stage telescopic plates and the U-shaped plate. The movement of a mobile suction device causes the suction position of the mobile suction device to overlap with the through slots. The suction force then acts into the turnover box through the through slots, bottom cavity slots, and multiple ventilation slots. This can gently and slowly peel off any thermal boundary layer that may exist on the surface of the electricity meter body. This process is also incorporated into the transportation process of the turnover box by the stacking and transportation device, which can effectively improve the transportation and storage efficiency for multiple electricity meters.

[0021] 2. The automated three-dimensional warehouse for smart meter storage described in this invention, when the turnover box and multiple meter bodies inside it are stacked into a predetermined position inside the storage rack by a stacking and transport device, the through groove and multiple connecting grooves at the bottom of the turnover box overlap. External suction equipment can then generate suction force in the top air duct and the hollow interior of the storage rack, and then suction can be carried out again through the through groove, bottom cavity groove and multiple ventilation holes. Without affecting storage, the thermal boundary layer on the outside of the meter body can be completely removed for a relatively long period of time without causing secondary dust pollution. Attached Figure Description

[0022] The invention will now be further described with reference to the accompanying drawings.

[0023] Figure 1 This is a perspective view of the entire invention;

[0024] Figure 2 This is a three-dimensional schematic diagram of the stacking and transport device in this invention;

[0025] Figure 3 This is a three-dimensional schematic diagram of the transfer device in this invention;

[0026] Figure 4 This is a three-dimensional schematic diagram of the mobile suction device in this invention;

[0027] Figure 5 This is a three-dimensional schematic diagram of the turnover box and the meter body in this invention;

[0028] Figure 6 This is a three-dimensional schematic diagram of the frame strip in this invention;

[0029] Figure 7 This is a three-dimensional schematic diagram of the turnover box in this invention;

[0030] Figure 8 This is a three-dimensional schematic diagram of the bottom cavity groove in this invention;

[0031] Figure 9 This is a three-dimensional schematic diagram of the V-groove and ventilation groove in this invention;

[0032] Figure 10 This is a three-dimensional schematic diagram of the connecting groove in this invention.

[0033] In the diagram: 1. Storage rack; 11. Shelf bar; 111. Connecting groove; 12. Ventilation groove; 13. V-groove; 14. Horizontal groove; 2. Turnover box; 21. Rib; 22. Ventilation hole groove; 23. Hollow strip plate; 24. Bottom cavity groove; 25. Through groove; 3. Top air duct; 4. Positioning box; 5. Stacking and transport device; 51. Guide rail; 52. Transport rack; 53. Transfer device; 531. U-shaped plate; 532. Multi-stage telescopic plate; 533. Component groove; 6. Electricity meter body; 7. Mobile suction device; 71. Fixed frame; 72. Fixed motor; 73. Telescopic rod; 74. Moving block; 741. Suction groove; 75. Air pipe. Detailed Implementation

[0034] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.

[0035] Example 1: As Figures 1-10 As shown, an automated three-dimensional warehouse for smart meter storage according to an embodiment of the present invention includes multiple storage racks 1 and a stacking and transporting device 5 movably installed between two storage racks 1. A positioning box 4 is installed on the side of the storage rack 1, and a turnover box 2 is positioned inside the positioning box 4. Multiple electric meter bodies 6 are placed inside the turnover box 2. A top air duct 3 is installed above the storage rack 1. The interior of the storage rack 1 is hollow, and the hollow interior of the storage rack 1 is connected to the air outlet of the top air duct 3.

[0036] The stacking and transport device 5 includes a transfer device 53, which includes a U-shaped plate 531 and component slots 533 opened inside both sides of the U-shaped plate 531. Multiple telescopic plates 532 are installed inside the U-shaped plate 531, and a mobile suction device 7 is installed inside the multiple component slots 533.

[0037] The bottom of the turnover box 2 is provided with a bottom cavity groove 24, the bottom of the bottom cavity groove 24 is provided with a through groove 25, and the top of the bottom cavity groove 24 is provided with a plurality of ventilation hole grooves 22.

[0038] The storage rack 1 has rack bars 11 installed on both sides. The turnover box 2 is placed on the four sets of rack bars 11 at the same horizontal level and adjacent to each other. The rack bars 11 have connecting grooves 111 inside, and the connecting grooves 111 are connected to the hollow interior of the storage rack 1.

[0039] Specifically, a positioning groove is opened at the top of the positioning box 4, and a transport groove is opened at the bottom. The turnover box 2, containing multiple meter bodies 6, is positioned in the positioning groove of the positioning box 4. At this time, the transfer device 53 moves to one side of the positioning box 4. Through the extension of the multi-stage telescopic plate 532, one end of the multi-stage telescopic plate 532 extends into the transport groove at the bottom of the positioning box 4. As the transfer device 53 rises, one end of the multi-stage telescopic plate 532 can drive the turnover box 2 to rise and detach from the positioning box 4. As the multi-stage telescopic plate 532 retracts, it will move the turnover box 2 above the U-shaped plate 531 and inside the U-shaped plate 531. At this time, the multiple through grooves 25 opened at the four corners of the bottom of the turnover box 2 are located in the multi-stage telescopic plate 532. At the gap between the inner walls of 32 and U-shaped plate 531, the movable suction device 7 moves so that its suction position overlaps with the through groove 25. The suction force then acts on the interior of the turnover box 2 through the through groove 25, bottom cavity groove 24, and multiple ventilation holes 22. This allows for a relatively slow and gentle removal of the thermal boundary layer that may exist on the surface of the meter body 6. This process is also incorporated into the transportation of the turnover box 2 by the stacking and transporting device 5, effectively improving the transportation and storage efficiency for multiple meter bodies 6. When the meter body 6 is calibrated and powered on, a thermal boundary layer forms around its surface. This thermal boundary layer exchanges heat with the air inside the storage area. After prolonged contact, the boundary layer reaches its dew point, forming water vapor. This water vapor then condenses on the casing and LCD. Micro-condensation occurs in the gaps. Traditional methods using air curtains to remove the thermal boundary layer and surface dust not only cause secondary dust pollution but also fail to gently and completely remove the thermal boundary layer from the surface of the meter body 6. In this device, when the transfer device 53 transports the turnover box 2, multiple mobile suction devices 7 can suction the turnover box 2 and multiple meter bodies 6 inside the U-shaped plate 531. This suction force gently removes the thermal boundary layer on the outside of the meter body 6 through the through groove 25, the bottom cavity groove 24, and multiple ventilation holes 22, thus benefiting the storage of the meter body 6. When the turnover box 2 and the multiple meter bodies 6 inside it are stacked into the storage rack 1 by the stacking and transport device 5, the meter body 6 is stored in a predetermined location. When positioned, the through groove 25 and multiple connecting grooves 111 at the bottom of the turnover box 2 overlap, allowing external suction equipment to generate suction force inside the top air duct 3 and the hollow interior of the storage rack 1. This suction then passes through the through groove 25, bottom cavity groove 24, and multiple ventilation holes 22, enabling long-term complete removal of the thermal boundary layer on the outside of the meter body 6 without affecting storage, and without causing secondary dust pollution. Because four external moisture sources—people, weather, buildings, and processes—are constantly brought in and accumulate in the relatively enclosed storage area, coupled with the meter body's weak heat dissipation, a layer of hot and humid air is formed, which contradicts the normal temperature and dry storage environment of the meter body 6. This device can address this through secondary suction.The hot, humid air inside the storage box 2 and the meter body 6 is drawn to the outside through the hollow interior of the storage rack 1 and the interior of the top air duct 3.

[0040] like Figures 2-3 As shown, the stacking and transporting device 5 includes two guide rails 51 fixedly installed at the top and bottom of the warehouse, a transport frame 52 movably installed between the two guide rails 51, and a transfer device 53 installed on one side of the transport frame 52.

[0041] The multi-stage telescopic plate 532 transports the turnover box 2 inside the positioning box 4 to the U-shaped plate 531 through multi-stage telescopic movement. The width of the multi-stage telescopic plate 532 is smaller than the width of the turnover box 2, and the width of the turnover box 2 is smaller than the distance between the inner walls on both sides of the U-shaped plate 531.

[0042] like Figure 4 As shown, the mobile suction device 7 includes a fixed frame 71 fixedly installed inside the component groove 533. A fixed motor 72 is fixedly installed inside the fixed frame 71. A telescopic rod 73 is installed on one side of the fixed motor 72. A movable block 74 is also movably installed inside the fixed frame 71. The side of the movable block 74 is connected to the end of the telescopic rod 73.

[0043] The movable block 74 has a suction groove 741 inside, and an air pipe 75 is installed below the suction groove 741. The other end of the air pipe 75 is connected to an external suction device.

[0044] When the telescopic rod 73 is fully extended, the suction groove 741 is connected to the corresponding through groove 25. The length and width of the suction groove 741, the through groove 25, and the connecting groove 111 are all equal.

[0045] Specifically, when the turnover box 2 is inside the U-shaped plate 531, because the width of the multi-stage telescopic plate 532 is smaller than the width of the turnover box 2, the multiple through slots 25 are located in the gap between the multi-stage telescopic plate 532 and the inner wall of the U-shaped plate 531. At this time, the telescopic rod 73 is extended by the drive of the fixed motor 72, so that the suction slot 741 moves inside the fixed frame 71 until the suction slot 741 is inside the U-shaped plate 531. At this time, the suction slot 741 is below the corresponding through slot 25, and the two overlap. The suction force is applied to the turnover box 2 through the air pipe 75, suction slot 741, through slot 25 and ventilation slot 22 by the external suction equipment, thereby gently removing the thermal boundary layer on the surface of the meter body 6 and the dust inside the turnover box 2.

[0046] Example 2: Figures 7-10 As shown in the first embodiment, another embodiment of the present invention is as follows: the inside of the turnover box 2 is equipped with a rib 21, which is used to regulate the placement of multiple electric meter bodies 6, and multiple hollow strips 23 are installed on the inner bottom of the turnover box 2.

[0047] The top of the hollow strip 23 is at the same horizontal level as the top of the ventilation slot 22. The bottom of the hollow strip 23 is connected to the outside. The hollow interior of the hollow strip 23 is not connected to the bottom cavity slot 24.

[0048] The hollow interior of the storage rack 1 includes a ventilation slot 12 formed inside the storage rack 1 and a plurality of transverse slots 14 formed on the side of the ventilation slot 12. The plurality of transverse slots 14 are connected to the corresponding connecting slots 111.

[0049] The storage rack 1 has a V-shaped groove 13 on its inner top, which is connected to the ventilation groove 12 and the interior of the top air duct 3.

[0050] Specifically, multiple meter bodies 6 are neatly placed inside the turnover box 2 by means of ribs 21 to avoid collisions. At this time, the hollow strip plate 23 facilitates air circulation between the inside and bottom of the turnover box 2, preventing heat accumulation during initial transportation and storage. When the top air duct 3 is performing suction, the hot and humid air or thermal boundary layer inside the turnover box 2 moves through the ventilation holes 22, bottom cavity groove 24, through groove 25, frame bar 11, horizontal groove 14, ventilation groove 12 and V-groove 13, which can directly and specifically address the locations in the warehouse that require hot and humid air treatment, thus helping to reduce energy consumption.

[0051] Working principle: The turnover box 2, containing multiple meter bodies 6, is positioned in the positioning slot of the positioning box 4. At this time, the transfer device 53 moves to one side of the positioning box 4. Through the extension of the multi-stage telescopic plate 532, one end of the multi-stage telescopic plate 532 extends into the transport slot opened at the bottom of the positioning box 4. As the transfer device 53 rises, one end of the multi-stage telescopic plate 532 can drive the turnover box 2 to rise and detach it from the positioning box 4. As the multi-stage telescopic plate 532 retracts, it moves the turnover box 2 above the U-shaped plate 531 and inside the U-shaped plate 531. At this time, the multiple through slots 25 opened at the four corners of the bottom of the turnover box 2 are in the gap between the inner wall of the multi-stage telescopic plate 532 and the U-shaped plate 531. The movable suction device 7 is moved so that its suction position overlaps with the through groove 25. The suction force then acts on the interior of the turnover box 2 through the through groove 25, the bottom cavity groove 24, and multiple ventilation holes 22. This allows for a relatively slow and gentle removal of the thermal boundary layer that may exist on the surface of the meter body 6. This process is also incorporated into the transportation of the turnover box 2 by the stacking and transporting device 5, effectively improving the transportation and storage efficiency for multiple meter bodies 6. When the meter body 6 is calibrated and powered on, a thermal boundary layer forms around its surface. This thermal boundary layer exchanges heat with the air inside the storage area. After prolonged contact, the boundary layer reaches its dew point, forming water vapor. This water vapor then condenses on the meter casing and LCD. Micro-condensation occurs in the gaps. Traditional methods using air curtains to remove the thermal boundary layer and surface dust not only cause secondary dust pollution but also fail to gently and completely remove the thermal boundary layer from the surface of the meter body 6. In this device, when the transfer device 53 transports the turnover box 2, multiple mobile suction devices 7 can suction the turnover box 2 and multiple meter bodies 6 inside the U-shaped plate 531. This suction force gently removes the thermal boundary layer on the outside of the meter body 6 through the through groove 25, the bottom cavity groove 24, and multiple ventilation holes 22, which is beneficial for the storage of the meter body 6. When the turnover box 2 and the multiple meter bodies 6 inside it are stacked into the predetermined position inside the storage rack 1 by the stacking and transport device 5, the through groove 25 and multiple connecting grooves 1 at the bottom of the turnover box 2... The 11-layer overlap allows for external suction to be generated within the hollow interior of the top duct 3 and storage rack 1, further drawing air through the through-hole 25, bottom cavity 24, and multiple ventilation holes 22. This allows for long-term complete removal of the thermal boundary layer on the outside of the meter body 6 without affecting storage conditions and without causing secondary dust pollution. Because four external moisture sources—people, weather, buildings, and processes—are constantly brought in and accumulate in the relatively enclosed storage area, coupled with the meter's weak heat dissipation, a layer of hot and humid air is formed, which contradicts the normal-temperature, dry storage environment of the meter body 6. This device uses secondary suction to draw the hot and humid air inside the turnover box 2 and the meter body 6 to the outside through the hollow interior of the storage rack 1 and the top duct 3.When the turnover box 2 is inside the U-shaped plate 531, because the width of the multi-stage telescopic plate 532 is smaller than the width of the turnover box 2, the multiple through slots 25 are located in the gap between the multi-stage telescopic plate 532 and the inner wall of the U-shaped plate 531. At this time, the telescopic rod 73 is extended by the drive of the fixed motor 72, causing the suction slot 741 to move inside the fixed frame 71 until the suction slot 741 is inside the U-shaped plate 531. At this time, the suction slot 741 is below the corresponding through slot 25, and the two overlap. The external suction device causes the suction force to pass through the air pipe 75, the suction slot 741, the through slot 25, and the ventilation slot 22 into the turnover box 2, thereby gently removing the thermal boundary layer on the surface of the meter body 6 and the dust inside the turnover box 2.

[0052] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. An automated three-dimensional warehouse for storing smart meters, comprising multiple storage racks (1) and a stacking and transport device (5) movably installed between two of the storage racks (1), wherein a positioning box (4) is installed on the side of each storage rack (1), and a turnover box (2) is positioned inside the positioning box (4), and multiple meter bodies (6) are placed inside the turnover box (2), characterized in that: A top air duct (3) is installed above the storage rack (1). The storage rack (1) is hollow inside, and the hollow interior of the storage rack (1) is connected to the air outlet of the top air duct (3). The stacking and transport device (5) includes a transfer device (53), which includes a U-shaped plate (531) and component slots (533) opened inside both sides of the U-shaped plate (531). Multiple telescopic plates (532) are installed inside the U-shaped plate (531), and a mobile suction device (7) is installed inside the multiple component slots (533). The bottom of the turnover box (2) is provided with a bottom cavity groove (24), the bottom of the bottom cavity groove (24) is provided with a through groove (25), and a plurality of ventilation holes (22) are provided above the bottom cavity groove (24). The storage rack (1) has rack bars (11) installed on both sides. The turnover box (2) is placed above four sets of rack bars (11) at the same horizontal height and adjacent to each other. The rack bars (11) have connecting grooves (111) inside, and the connecting grooves (111) are connected to the hollow interior of the storage rack (1).

2. The automatic stereoscopic warehouse for storing intelligent electric meters according to claim 1, characterized in that: The stacking and transport device (5) includes two guide rails (51) fixedly installed at the top and bottom of the warehouse, a transport frame (52) is movably installed between the two guide rails (51), and the transfer device (53) is installed on one side of the transport frame (52).

3. The automatic warehouse for storing intelligent electric meters according to claim 1, characterized in that: The multi-stage telescopic plate (532) transports the turnover box (2) inside the positioning box (4) to the U-shaped plate (531) through multi-stage telescopic movement. The width of the multi-stage telescopic plate (532) is smaller than the width of the turnover box (2), and the width of the turnover box (2) is smaller than the distance between the inner walls on both sides of the U-shaped plate (531).

4. The automatic warehouse for storing intelligent electric meters according to claim 1, characterized in that: The mobile suction device (7) includes a fixed frame (71) fixedly installed inside the component groove (533). A fixed motor (72) is fixedly installed inside the fixed frame (71). A telescopic rod (73) is installed on one side of the fixed motor (72). A movable block (74) is also movably installed inside the fixed frame (71). The side of the movable block (74) is connected to the end of the telescopic rod (73).

5. The automatic stereoscopic warehouse for storing intelligent electric meters according to claim 4, characterized in that: The movable block (74) has a suction groove (741) inside, and an air pipe (75) is installed below the suction groove (741). The other end of the air pipe (75) is connected to an external suction device.

6. The automatic stereoscopic warehouse for storing intelligent electric meters according to claim 5, characterized in that: When the telescopic rod (73) is fully extended, the suction groove (741) is connected to the corresponding through groove (25), and the length and width of the suction groove (741), through groove (25) and connecting groove (111) are all equal.

7. The automatic warehouse for storing intelligent electric meters according to claim 1, characterized in that: The turnover box (2) is equipped with a rib (21) inside, which is used to regulate the placement of multiple electric meter bodies (6). Multiple hollow strips (23) are installed on the inner bottom of the turnover box (2).

8. The automatic stereoscopic warehouse for storing intelligent electric meters according to claim 7, characterized in that: The top of the hollow strip (23) is at the same horizontal level as the top of the ventilation slot (22), the bottom of the hollow strip (23) is connected to the outside, and the hollow interior of the hollow strip (23) is not connected to the bottom cavity slot (24).

9. The automatic warehouse for storing intelligent electric meters according to claim 1, characterized in that: The hollow interior of the storage rack (1) includes a ventilation slot (12) opened inside the storage rack (1) and a plurality of transverse slots (14) opened on the side of the ventilation slot (12), and the plurality of transverse slots (14) are connected to the corresponding connecting slots (111).

10. The automatic stereoscopic warehouse for storing intelligent electric meters according to claim 9, characterized in that: The storage rack (1) has a V-shaped groove (13) on its inner top, which is connected to the ventilation groove (12) and the interior of the top air duct (3).