CN117741215A

CN117741215A - Intelligent electric energy information transmission device and application method thereof

Info

Publication number: CN117741215A
Application number: CN202410183472.9A
Authority: CN
Inventors: 张永强; 乔君; 王芳; 彭洋; 孟杨; 胡恒; 周封; 孔祥玉; 徐凤霞; 田静琦
Original assignee: State Grid Corp of China SGCC; State Grid Heilongjiang Electric Power Co Ltd
Current assignee: State Grid Corp of China SGCC; State Grid Heilongjiang Electric Power Co Ltd
Priority date: 2024-02-19
Filing date: 2024-02-19
Publication date: 2024-03-22
Anticipated expiration: 2044-02-19
Also published as: CN117741215B

Abstract

An intelligent electric energy information transmission device and a use method thereof belong to the field of electric energy meters. The electric energy meter comprises an electric energy meter body, side baffles, a control device I and a control device II; the front side and the rear side of the bottom of the electric energy meter body are fixedly connected with side baffles; the electric energy meter body comprises a shell; the bottom of the shell is provided with an arc-shaped groove I and an arc-shaped groove II; the control device I is located the inside of shell and with I sliding fit of arc wall, and the control device II is located the outside bottom of shell and with II sliding fit of arc wall. According to the invention, dust on the dust screen can be cleaned, insects can be reduced from entering the electric energy meter, meanwhile, the electric energy meter can be sealed through the control device I, heat loss is reduced in winter, the temperature is kept constant, the sponge can be extruded through the control device II, and the reduction of air flow rate caused by the saturation of the sponge adsorption water vapor is avoided, so that heat dissipation is affected.

Description

Intelligent electric energy information transmission device and application method thereof

Technical Field

The invention relates to an intelligent electric energy information transmission device and a use method thereof, and belongs to the field of electric energy meters.

Background

The radiating structure of traditional electric energy meter shell is formed by directly punching holes in the upper cover or the bottom shell of the electric energy meter, and along with the increase of the service time of the electric energy meter, the radiating hole of the radiating mechanism is covered by dust easily, so that the radiating effect is affected, the cleaning of dust is difficult for workers, insects easily enter the electric energy meter from the radiating hole, the electric wire is damaged, and the safety of the electric energy meter cannot be guaranteed. In addition, when raining, the steam in the air can get into the electric energy meter inside through the louvre, causes the influence to its inside electronic component's life, consequently it is necessary to improve it.

Disclosure of Invention

The invention aims to solve the problems in the background art and provides an intelligent electric energy information transmission device and a use method thereof.

The invention achieves the above purpose, adopts the following technical scheme:

an intelligent electric energy information transmission device comprises an electric energy meter body, side baffles, a control device I and a control device II; the front side and the rear side of the bottom of the electric energy meter body are fixedly connected with side baffles; the electric energy meter body comprises a shell; the bottom of the shell is provided with an arc-shaped groove I and an arc-shaped groove II; the control device I is located the inside of shell and with I sliding fit of arc wall, and the control device II is located the outside bottom of shell and with II sliding fit of arc wall.

The bottom of the shell is also provided with two perforations and an air inlet; the arc-shaped groove I is positioned between the air inlet and the perforation closest to the air inlet, and the arc-shaped groove II is positioned at the other side of the air inlet; a dust screen is fixedly connected in the air inlet;

the control device I comprises an arc-shaped plate I and a baffle, the baffle is fixedly connected to the bottom wall of the shell between two perforations, one end of the arc-shaped plate I is in contact with the baffle, the other end of the arc-shaped plate I is in sliding fit with the arc-shaped groove II, and two sides of the arc-shaped plate I are in contact with the inner side wall of the shell;

the control device II comprises an arc-shaped plate II, an arc-shaped plate III and an arc-shaped plate IV; the arc plate II is fixedly connected to the bottom end of the shell, one end of the arc plate III is in contact with the arc plate II, the other end of the arc plate III is fixedly connected with the arc plate IV through the fixing rod I, and the other end of the arc plate IV is in sliding fit with the arc groove I; the two perforations are positioned in an arc-shaped space surrounded by the arc-shaped plate II, the arc-shaped plate III and the arc-shaped plate IV;

and a foam cushion is fixedly connected between the arc-shaped plate IV and the baffle. An application method of an intelligent electric energy information transmission device comprises the following steps:

step one: when ventilation and heat dissipation are carried out, external air enters the shell through the air inlet, the foam-rubber cushion and the two perforations to carry out heat dissipation;

step two: after the sponge cushion is saturated by adsorbing moisture; the transmission device drives the arc-shaped plate IV to rotate, the foam-rubber cushion is extruded, water falls into the space between the arc-shaped plate IV and the sliding plate through the perforation to be stored, and then the transmission device is reversely started to enable the arc-shaped plate IV to move to the original position;

step three: and the other transmission device is started to drive the arc plate I to move, so that the arc plate I moves into the embedded groove, the air inlet is sealed, the internal temperature is ensured to be constant, the heat dissipation is reduced, and meanwhile, the rotating rod I and the rotating rod II are pushed to move through the pressing plate, so that the brush hair is driven to sweep dust on the dust screen.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, dust on the dust screen can be cleaned, insects can be reduced from entering the electric energy meter, meanwhile, the electric energy meter can be sealed through the control device I, heat loss is reduced in winter, the temperature is kept constant, the sponge can be extruded through the control device II, and the reduction of air flow rate caused by the saturation of the sponge adsorption water vapor is avoided, so that heat dissipation is affected.

Drawings

Fig. 1 is a front view of an intelligent power information transmission device according to the present invention;

fig. 2 is a schematic structural view of a housing of an intelligent power information transmission device according to the present invention;

FIG. 3 is a schematic diagram of a transmission device of an intelligent electric energy information transmission device according to the present invention;

FIG. 4 is a schematic structural view of a cleaning device of an intelligent power information transmission device according to the present invention;

fig. 5 is a front view of a control device i of an intelligent power information transmission device according to the present invention;

FIG. 6 is a cross-sectional view of a control device II of an intelligent power information transmission device according to the present invention;

fig. 7 is a front view of a control device ii of an intelligent power information transmission device according to the present invention;

FIG. 8 is a schematic diagram of the position of a water flow hole I of an intelligent electric energy information transmission device according to the present invention;

fig. 9 is a schematic structural diagram of a heat dissipation state of an intelligent power information transmission device according to the present invention;

fig. 10 is a schematic structural view of a sealing state of an intelligent power information transmission device according to the present invention;

FIG. 11 is a schematic diagram of a sponge dehydration state of an intelligent electric energy information transmission device according to the present invention;

fig. 12 is a schematic diagram showing a sponge dehydration state of an intelligent electric energy information transmission device according to the present invention.

In the figure: 1. an electric energy meter body; 11. a housing; 12. perforating; 13. a groove; 14. an arc-shaped groove II; 15. an arc-shaped groove I; 16. a transmission device; 161. a transmission rod; 162. a drive plate; 163. a motor; 17. an air inlet; 18. a dust screen; 19. a cleaning device; 191. a rotating rod I; 192. a rotating rod II; 193. brushing; 2. side baffles; 3. a control device I; 31. a baffle; 32. an arc-shaped plate I; 33. a chute I; 34. a bump; 35. a sponge cushion; 36. a pressing plate; 4. a control device II; 41. an arc-shaped plate II; 42. an arc-shaped plate III; 43. a limiting plate; 431. a water flow hole I; 44. an embedding groove; 45. a slide plate; 46. a through hole I; 47. a spring I; 48. a fixed rod I; 49. an arc-shaped plate IV; 50. a groove; 51. an arc-shaped plate V; 52. triangular blocks; 53. a connecting rod; 54. a spring II; 55. a through hole III; 56. a fixed rod II; 57. a sealing plate; 58. arc-shaped protruding blocks; 59. a rotating shaft; 60. a movable plate; 64. and a chute II.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present invention are all within the protection scope of the present invention.

The first embodiment is as follows: as shown in fig. 1-12, this embodiment describes an intelligent electric energy information transmission device, which includes an electric energy meter body 1, a side baffle 2, a control device i 3 and a control device ii 4; the front side and the rear side of the bottom of the electric energy meter body 1 are fixedly connected with side baffles 2; the electric energy meter body 1 comprises a shell 11; the bottom of the shell 11 is provided with an arc-shaped groove I15 and an arc-shaped groove II 14; the control device I3 is located inside the shell 11 and is in sliding fit with the arc-shaped groove I15, and the control device II 4 is located at the bottom end outside the shell 11 and is in sliding fit with the arc-shaped groove II 14.

The bottom of the shell 11 is also provided with two perforations 12 and an air inlet 17; the arc-shaped groove I15 is positioned between the air inlet 17 and the perforation 12 closest to the air inlet 17, and the arc-shaped groove II 14 is positioned at the other side of the air inlet 17; and a dust screen 18 is fixedly connected in the air inlet 17.

The control device I3 comprises an arc-shaped plate I32 and a baffle plate 31, the baffle plate 31 is fixedly connected to the bottom wall of the shell 11 between the two perforations 12, one end of the arc-shaped plate I32 is in contact with the baffle plate 31, the other end of the arc-shaped plate I32 is in sliding fit with the arc-shaped groove II 14, and two sides of the arc-shaped plate I32 are in contact with the inner side wall of the shell 11.

The control device II 4 comprises an arc-shaped plate II 41, an arc-shaped plate III 42 and an arc-shaped plate IV 49; the arc plate II 41 is fixedly connected to the bottom end of the shell 11, one end of the arc plate III 42 is in contact with the arc plate II 41, the other end of the arc plate III 42 is fixedly connected with the arc plate IV 49 through the fixing rod I48, and the other end of the arc plate IV 49 is in sliding fit with the arc groove I15; the two through holes 12 are positioned in an arc-shaped space surrounded by the arc-shaped plate II 41, the arc-shaped plate III 42 and the arc-shaped plate IV 49.

The inner circular surface of the arc-shaped plate I32 is fixedly connected with a pressing plate 36, and the inner wall of the shell 11 is provided with a cleaning device 19; the cleaning device 19 comprises a rotating rod I191; the rotating rod I191 is connected to the inner wall of the shell 11 through a spring hinge, and the other end of the rotating rod I191 is connected with a rotating rod II 192 through a spring hinge; the other end of the rotating rod II 192 is provided with a spherical head, and the spherical head is provided with bristles 193 which are contacted with the dust screen 18.

A foam cushion 35 is fixedly connected between the arc-shaped plate IV 49 and the baffle 31.

A sliding plate 45 is arranged between the arc-shaped plate III 42 and the arc-shaped plate IV 49; the sliding plate 45 is provided with a through hole I46 in sliding fit with a fixed rod I48, and a spring I47 is fixedly connected between the fixed rod I48 and the inner wall of the through hole I46; the sliding plate 45 is also provided with a through hole II, and a fixing rod II 56 is fixedly connected in the through hole II; a sealing plate 57 is arranged in the through hole II; the sealing plate 57 is fixedly connected with a connecting rod 53; the connecting rod 53 is provided with a through hole III 55 which is in sliding fit with the fixing rod II 56; a spring II 54 is fixedly connected between the fixed rod II 56 and the inner wall of the through hole III 55; the other end of the connecting rod 53 is connected with a triangular block 52 through a spring hinge; the inner circular surface of the arc-shaped plate IV 49 is provided with a groove 50, and an arc-shaped plate V51 is connected in the groove 50 through a spring hinge; the arcuate plate iv 49 is located below the perforations 12 adjacent the air inlet 17.

A limiting plate 43 is fixedly connected to the inner circular surface of the arc-shaped plate III 42, and two water flowing holes I431 are formed in one end, close to the inner circular surface of the arc-shaped plate III 42, of the limiting plate 43; a rotating shaft 59 is fixedly connected between the two side baffles 2; the rotating shaft 59 is provided with a movable plate 60, and a coil spring is arranged at the joint of the movable plate 60 and the rotating shaft 59; one end of the movable plate 60 is contacted with the inner circular surface of the arc-shaped plate III 42, the other end of the movable plate 60 is provided with an arc-shaped protruding block 58, and the bottom of the shell 11 is provided with a groove 13 in sliding fit with the arc-shaped protruding block 58.

A transmission device 16 is arranged in each of the arc-shaped groove I15 and the arc-shaped groove II 14; the transmission device 16 comprises a transmission rod 161, a transmission plate 162 and a motor 163; the motor 163 is fixedly connected to the outer side of the shell 11, one end of the transmission rod 161 is fixedly connected to an output shaft of the motor 163, the transmission rod 161 is positioned in the corresponding arc-shaped groove I15 and arc-shaped groove II 14, and a plurality of transmission plates 162 are fixedly connected to the outer round surface of the transmission rod 161; the side surfaces of the arc-shaped plate I32 and the arc-shaped plate IV 49 are respectively provided with a chute I33 and a chute II 64; the inner walls of one side of the sliding grooves I33 and II 64 are provided with clamping grooves which are in sliding fit with the transmission plate 162, and the corresponding clamping grooves are embedded in the rotation process of the transmission plate 162 so as to drive the arc plates I32 and IV 49 to move; the connecting ends of the arc-shaped plate III 42, the arc-shaped plate IV 49 and the fixed rod I48 are respectively provided with an embedded groove 44; hemispherical convex blocks 34 are fixedly connected to the arc-shaped plate I32, and the convex blocks 34 push the sliding plate 45 to move when being positioned in the embedded grooves 44.

An application method of an intelligent electric energy information transmission device comprises the following steps:

step one: when ventilation and heat dissipation are carried out, external air enters the shell 11 through the air inlet 17, the foam cushion 35 and the two perforations 12 for heat dissipation;

step two: after saturation of the foam pad 35 with moisture; the transmission device 16 drives the arc-shaped plate IV 49 to rotate, the foam cushion 35 is extruded, water falls into a space between the arc-shaped plate IV 49 and the sliding plate 45 through the perforation 12 for storage, and then the transmission device 16 is reversely started to enable the arc-shaped plate IV 49 to move to the original position;

step three: the other transmission device 16 is started to drive the arc plate I32 to move, the arc plate I32 is moved into the embedded groove 44, the air inlet 17 is sealed, the internal temperature is guaranteed to be constant, heat dissipation is reduced, meanwhile, the rotating rod I191 and the rotating rod II 192 are pushed to move through the pressing plate 36, and the brush hair 193 is driven to sweep dust on the dust screen 18.

The working principle of the invention is as follows: when the device is used for heat dissipation, the control device I3 and the control device II 4 are moved to the state shown in fig. 9, external air passes through the dustproof net 18 on the air inlet 17, enters into a space surrounded by the control device I3 and the shell 11, then passes through the sponge cushion 35 to absorb moisture in the air, then passes through the perforation 12, enters into the space surrounded by the control device II 4 and the shell 11, passes through the groove 13, then passes through the other perforation 12, and enters into the shell 11 for heat dissipation;

both sides of the arc-shaped plate V51, the movable plate 60 and the sliding plate 45 are contacted with the inner wall of the side baffle plate 2, so that insects can be blocked by the arc-shaped plate V51, the movable plate 60 and the sponge cushion 35 even if the insects enter the control device I3 and the control device II 4 through the dust-proof net 18, and the insects are prevented from entering the electric energy meter;

when the outside is cold, the motor 163 is started, the motor 163 drives the transmission rod 161 to rotate so as to drive the transmission plate 162 to move, the transmission plate 162 drives the arc plate I32 to rotate from the state shown in fig. 10 through being matched with the clamping groove on the inner wall of the chute I33, the end of the arc plate I32, which is provided with the hemispherical convex block 34, is inserted into the embedded groove 44, the air inlet 17 is shielded, so that heat loss is reduced, meanwhile, the arc plate I32 also drives the pressing plate 36 to move, when the pressing plate 36 contacts the joint of the rotating rod I191 and the rotating rod II 192, the rotating rod I191 and the rotating rod II 192 are driven to move along with the movement of the pressing plate 36, and the bristles 193 at the end part of the rotating rod II 192 sweep dust on the dust screen 18, so that blockage is avoided; simultaneously, the lug 34 pushes the sliding plate 45 to move, so that the top end of the sliding plate 45 pushes the arc-shaped lug 58 to rotate upwards around the rotating shaft 59 until contacting with the top wall of the groove 13, and drives the movable plate 60 to rotate downwards around the rotating shaft 59, so that the movable plate 60 and the limiting plate 43 are abutted together, and a plurality of cavities are formed in the control device II 4, so that the heat preservation effect is enhanced;

when the foam cushion 35 is saturated, the other motor 163 is started, the transmission plate 162 corresponding to the motor 163 drives the arc plate IV 49 to move towards the inside of the outer shell 11 through matching with the clamping groove on the inner wall of the sliding groove II 64, as shown in the state of figures 11-12, the arc plate IV 49 drives the arc plate III 42 and the sliding plate 45 to rotate together through the fixing rod I48 in the rotating process of the arc plate IV 49, the arc plate V51 enters the arc groove I15 along with the movement of the arc plate IV 49, the arc plate V51 gradually moves towards the direction of the groove 50 under the limiting effect of the arc groove I15, the arc plate V51 gradually breaks away from the sliding plate 45 in the moving process, the triangular block 52 is pushed to move, the sealing plate 57 is driven to move towards the direction of the arc plate III 42 by the connecting rod 53, the through hole II is exposed until the arc plate V51 is separated from the triangular block 52, the sealing plate 57 moves back to the original position under the action of the spring II 54, meanwhile, in the rotating process of the arc plate IV 49, the sliding plate 45 rotates together with the arc plate IV, the sliding plate 45 is gradually separated from the arc-shaped protruding block 58, the movable plate 60 rotates under the action of the elasticity of a coil spring arranged between the movable plate 60 and the rotating shaft 59, and the movable plate 60 after rotation abuts against the lower end of the through hole 12 at the left side shown in fig. 12, so that dust is reduced from entering the shell 11; along with the rotation of the arc-shaped plate IV 49, the foam-rubber cushion 35 is driven to deform, the foam-rubber cushion 35 is extruded, water in the foam-rubber cushion 35 is extruded, the foam-rubber cushion passes through the perforations 12 and falls on the upper end of the sliding plate 45 under the action of gravity, after the motor 163 is reversely started, the arc-shaped plate IV 49 moves to the original position, the sliding plate 45 contacts with the arc-shaped protruding block 58, the arc-shaped protruding block 58 is driven to move into the groove 13 again, the perforations 12 are exposed, meanwhile, the arc-shaped plate V51 moves away from the groove 50 under the action of a spring hinge, when the arc-shaped plate V51 contacts with the triangular block 52 from bottom to top, the triangular block 52 is pushed to rotate around the spring hinge connected with the triangular block until the arc-shaped plate V51 is separated from the triangular block 52 and contacts with the side face of the sliding plate 45, in the process of moving to the original position, water flows to the upper end of the arc-shaped plate IV 49 along a gap between the arc-shaped plate V51 under the action of gravity, after the arc-shaped plate V51 contacts with the sliding plate 45, the arc-shaped plate V51 and the V51 is enclosed in a space, the foam-rubber cushion 35 is extruded out of the foam-rubber cushion along with the space, the air is prevented from flowing out of the foam-rubber cushion through the water cushion through the waterproof cushion, and the foam-rubber cushion is prevented from flowing out of the moisture through the waterproof cushion through the air cushion casing, and the foam-rubber cushion casing, and the moisture is prevented from flowing out of the moisture from the foam-rubber cushion casing through the air through the ventilation hole through the through hole and the through hole I when the foam-shaped cushion is discharged through the step I is discharged through the heat-proof hole.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. An intelligent electric energy information transmission device is characterized in that: comprises an electric energy meter body (1), a side baffle (2), a control device I (3) and a control device II (4); the front side and the rear side of the bottom of the electric energy meter body (1) are fixedly connected with side baffles (2); the electric energy meter body (1) comprises a shell (11); an arc-shaped groove I (15) and an arc-shaped groove II (14) are arranged at the bottom of the shell (11); the control device I (3) is positioned in the shell (11) and is in sliding fit with the arc-shaped groove I (15), and the control device II (4) is positioned at the bottom end of the outer part of the shell (11) and is in sliding fit with the arc-shaped groove II (14);

the bottom of the shell (11) is also provided with two perforations (12) and an air inlet (17); the arc-shaped groove I (15) is positioned between the air inlet (17) and the perforation (12) closest to the air inlet, and the arc-shaped groove II (14) is positioned at the other side of the air inlet (17); a dust screen (18) is fixedly connected in the air inlet (17);

the control device I (3) comprises an arc-shaped plate I (32) and a baffle plate (31), the baffle plate (31) is fixedly connected to the bottom wall of the shell (11) between two through holes (12), one end of the arc-shaped plate I (32) is in contact with the baffle plate (31), the other end of the arc-shaped plate I (32) is in sliding fit with the arc-shaped groove II (14), and two sides of the arc-shaped plate I (32) are in contact with the inner side wall of the shell (11);

the control device II (4) comprises an arc-shaped plate II (41), an arc-shaped plate III (42) and an arc-shaped plate IV (49); the arc plate II (41) is fixedly connected to the bottom end of the shell (11), one end of the arc plate III (42) is in contact with the arc plate II (41), the other end of the arc plate III (42) is fixedly connected with the arc plate IV (49) through the fixing rod I (48), and the other end of the arc plate IV (49) is in sliding fit with the arc groove I (15); the two perforations (12) are positioned in an arc-shaped space surrounded by an arc-shaped plate II (41), an arc-shaped plate III (42) and an arc-shaped plate IV (49);

a foam cushion (35) is fixedly connected between the arc-shaped plate IV (49) and the baffle plate (31).

2. The intelligent power information transmission device according to claim 1, wherein: the inner circular surface of the arc-shaped plate I (32) is fixedly connected with a pressing plate (36), and a cleaning device (19) is arranged on the inner wall of the shell (11); the cleaning device (19) comprises a rotating rod I (191); the rotating rod I (191) is connected to the inner wall of the shell (11) through a spring hinge, and the other end of the rotating rod I (191) is connected with the rotating rod II (192) through a spring hinge; the other end of the rotating rod II (192) is provided with a spherical head, and the spherical head is provided with bristles (193) contacted with the dust screen (18).

3. The intelligent power information transmission device according to claim 2, wherein: a sliding plate (45) is arranged between the arc-shaped plate III (42) and the arc-shaped plate IV (49); the sliding plate (45) is provided with a through hole I (46) in sliding fit with a fixed rod I (48), and a spring I (47) is fixedly connected between the fixed rod I (48) and the inner wall of the through hole I (46); the sliding plate (45) is also provided with a through hole II, and a fixing rod II (56) is fixedly connected in the through hole II; a sealing plate (57) is arranged in the through hole II; a connecting rod (53) is fixedly connected to the sealing plate (57); the connecting rod (53) is provided with a through hole III (55) which is in sliding fit with the fixed rod II (56); a spring II (54) is fixedly connected between the fixed rod II (56) and the inner wall of the through hole III (55); the other end of the connecting rod (53) is connected with a triangular block (52) through a spring hinge; a groove (50) is arranged on the inner circular surface of the arc-shaped plate IV (49), and an arc-shaped plate V (51) is connected in the groove (50) through a spring hinge; the arc-shaped plate IV (49) is positioned below the perforation (12) close to the air inlet (17).

4. An intelligent transmission device for electric energy information according to claim 3, wherein: a limiting plate (43) is fixedly connected to the inner circular surface of the arc-shaped plate III (42), and two water flowing holes I (431) are formed in one end, close to the inner circular surface of the arc-shaped plate III (42), of the limiting plate (43); a rotating shaft (59) is fixedly connected between the two side baffles (2); a movable plate (60) is arranged on the rotating shaft (59), and a coil spring is arranged at the joint of the movable plate (60) and the rotating shaft (59); one end of the movable plate (60) is contacted with the inner circular surface of the arc-shaped plate III (42), the other end of the movable plate (60) is provided with an arc-shaped protruding block (58), and the bottom of the shell (11) is provided with a groove (13) which is in sliding fit with the arc-shaped protruding block (58).

5. The intelligent power information transmission device according to claim 4, wherein: a transmission device (16) is arranged in each of the arc-shaped groove I (15) and the arc-shaped groove II (14); the transmission device (16) comprises a transmission rod (161), a transmission plate (162) and a motor (163); the motor (163) is fixedly connected to the outer side of the shell (11), one end of the transmission rod (161) is fixedly connected to an output shaft of the motor (163), the transmission rod (161) is positioned in the corresponding arc-shaped groove I (15) and arc-shaped groove II (14), and a plurality of transmission plates (162) are fixedly connected to the outer circular surface of the transmission rod (161); the side surfaces of the arc-shaped plate I (32) and the arc-shaped plate IV (49) are respectively provided with a chute I (33) and a chute II (64); the inner walls of one side of the sliding grooves I (33) and the sliding grooves II (64) are provided with clamping grooves which are in sliding fit with the transmission plate (162), and the corresponding clamping grooves are embedded in the rotation process of the transmission plate (162) to drive the arc-shaped plates I (32) and IV (49) to move; the connecting ends of the arc-shaped plate III (42), the arc-shaped plate IV (49) and the fixed rod I (48) are respectively provided with an embedded groove (44); hemispherical convex blocks (34) are fixedly connected to the arc-shaped plates I (32), and the convex blocks (34) push the sliding plates (45) to move when being positioned in the embedded grooves (44).

6. The method for using an intelligent power information transmission device according to claim 5, wherein: the using method comprises the following steps:

step one: when ventilation and heat dissipation are carried out, external air enters the shell (11) through the air inlet (17), the foam-rubber cushion (35) and the two perforations (12) to dissipate heat;

step two: after the foam cushion (35) is saturated by adsorbing moisture; the transmission device (16) drives the arc-shaped plate IV (49) to rotate, the sponge cushion (35) is extruded, water falls into a space between the arc-shaped plate IV (49) and the sliding plate (45) through the perforation (12) to be stored, and then the transmission device (16) is reversely started to enable the arc-shaped plate IV (49) to move to a home position;

step three: and the other transmission device (16) is started to drive the arc-shaped plate I (32) to move, so that the arc-shaped plate I (32) moves into the embedded groove (44), the air inlet (17) is sealed, the internal temperature is ensured to be constant, heat dissipation is reduced, meanwhile, the rotating rod I (191) and the rotating rod II (192) are pushed to move through the pressing plate (36), and the bristles (193) are driven to sweep dust on the dust screen (18).