CN115999329B - Power load information data collector - Google Patents

Abstract

The invention discloses a power load information data collector, which relates to the technical field of power information detection equipment. It includes a collection unit and a dehumidification unit. The collection unit includes a data collection module. The dehumidification unit includes a water collection module and at least one dehumidification fan. , the dehumidification fan is arranged above the water collection module, and the dehumidification fan is used to blow the heat generated by the data acquisition module into the water collection module. The power load information data collector of the invention can automatically remove internal moisture, reduce the temperature difference between inside and outside, and prevent moisture from condensing into water on circuit equipment.

Description

Electric load information data collector

Technical field

The invention relates to the technical field of electric power information detection equipment, and in particular to an electric load information data collector.

Background technique

In daily production or life, it is often necessary to monitor the power load in real time to adjust the power transmission status. The power load information data collector is a common power load information data collection device. It can collect, analyze and evaluate the power load information of electrical equipment, and combine it with massive data on the operation of electrical equipment to provide distribution network dispatching for power supply. Provide more accurate load forecasting information.

However, current power load information data collectors are often set up indoors. In outdoor scenarios where a large amount of electricity is used, such as sports games, large-scale exhibitions, outdoor performances, etc., cold weather or large temperature differences between morning and evening often lead to data collection. The surface of the data collector is covered with frost, and the inside of the data collector has a high temperature due to the heat generated by the electrical equipment during operation. It is also easy to condense into water in the data collector when it is cold, resulting in moisture in the wiring position inside the data collector, which not only affects The data collection accuracy of the data collector is affected, and it is more likely to cause a short circuit at the wiring and cause danger. Therefore, there is an urgent need for a big data power load information data collector that can dehumidify in time to solve the above problems.

Contents of the invention

The object of the present invention is to provide an electric power load information data collector that can automatically remove internal moisture, reduce the temperature difference between inside and outside, and prevent moisture from condensing into water on circuit equipment.

The above objects of the present invention can be achieved by adopting the following technical solutions:

The invention provides a power load information data collector, which includes a collection unit and a dehumidification unit. The collection unit includes a data collection module. The dehumidification unit includes a water collection module and at least one dehumidification fan. The dehumidification fan is arranged on the Above the water collection module, the dehumidification fan is used to blow the heat generated by the data acquisition module into the water collection module.

In a preferred embodiment, the acquisition unit includes a first box, a first accommodation space is formed on the upper part of the first box, and the data acquisition module is arranged in the first accommodation space;

The dehumidification unit includes a second box body, the second box body is formed with a second accommodation space, the water collection module is arranged in the second accommodation space, and the dehumidification fan is arranged in the second box body. the upper end of;

Wherein, the first box cover is provided on the second box, and the first accommodating space and the second accommodating space are connected, so that the heat generated by the data acquisition module can enter the third accommodating space. 2. Within the accommodation space.

In a preferred embodiment, the water collecting module includes a water collecting box and at least one water collecting mechanism. The water collecting box is arranged in contact with the lower part of the first box. The water collecting box A third accommodation space is formed inside the body, and the water collecting mechanism is arranged in the third accommodation space;

The water collection mechanism includes:

The condensation fin is fixedly connected to the inner wall of the water collecting box, and a movable groove is formed in the middle of the condensation fin;

The upper edge of the water collecting bucket is arranged in close contact with the condensation plate;

The contact piece is fixedly connected to the water collecting bucket, and the touching piece and the water collecting bucket are respectively located on both sides of the condensation plate;

A first elastic member, both ends of which are respectively connected to the lower end of the contact member and the bottom of the water collection box, and the first elastic member is used to support the contact member and the water collection bucket;

At least one touch switch is provided on the inner wall of the water collection box, and the touch switch is used to control the dehumidification fan;

Wherein, the water collecting bucket and the contact piece can move up and down along the movable groove, and the contact piece can touch the touch switch to start or stop the rotation of the dehumidification fan.

In a preferred embodiment, the number of the dehumidification fans is multiple, and the plurality of dehumidification fans are arranged in parallel at the upper end of the second box. The number of the touch switches is equal to the number of the dehumidification fans. Similarly, a plurality of the touch switches are arranged side by side on the inner wall of the water collection box along the up and down direction, and the plurality of touch switches respectively control a plurality of the dehumidification fans.

In a preferred embodiment, the dehumidification unit includes a heat conduction mechanism, and the heat conduction mechanism is provided on the water collection box;

The heat conduction mechanism includes:

Thermal conductive grille has multiple thermal conductive plates arranged side by side;

A heat-conducting tube is formed by extending downward from the heat-conducting grille. The heat-conducting tube extends into the water collection box. A plurality of air outlets are formed on the lower end of the heat-conducting tube along the circumferential direction;

A thermally conductive cover plate is provided at the lower end of the thermally conductive cylinder, and the peripheral edge of the thermally conductive cover plate extends upward to form a shielding portion, and the shielding portion is used to shield a plurality of the air outlets;

A support frame is fixedly connected in the heat-conducting cylinder, and the heat-conducting cover is movably connected to the support frame through a second elastic member;

Wherein, the dehumidification airflow formed by the dehumidification fan can pass through the heat conduction grille and enter the heat conduction cylinder, and the dehumidification airflow can blow the heat conduction cover plate to move downward to expose at least part of the heat conduction cover. An air outlet through which the dehumidified airflow can enter the water collecting box.

In a preferred embodiment, the support frame has an annular portion and a connecting portion, and the connecting portion extends radially outward from the annular portion to the inner wall of the heat-conducting cylinder, so that the supporting frame Fixedly connected in the heat-conducting cylinder, the two ends of the second elastic member are respectively connected to the annular portion and the heat-conducting cover plate;

The thermal conductive mechanism also includes a limiting shaft, which is fixedly connected to the thermally conductive cover plate and passes through the annular portion. A plurality of limiting portions are formed on the upper end of the limiting shaft. The limiting portion can be locked on the upper end of the annular portion, so that the limiting shaft limits the downward movement range of the thermally conductive cover plate.

In a preferred embodiment, the heat conduction plate is inclined from top to bottom toward the middle of the heat conduction grille, so that the dehumidification airflow enters the heat conduction cylinder.

In a preferred embodiment, ventilation openings are formed on both sides of the second box;

The dehumidification unit includes a ventilation mechanism, which is arranged in the second accommodation space and located above the heat conduction mechanism;

The ventilation mechanism includes:

A first rotating shaft corresponding to the lower ends of the ventilation openings provided on both sides of the second box;

a second rotating shaft corresponding to the upper ends of the ventilation openings provided on both sides of the second box;

A shielding film with two ends respectively connected to the first rotating shaft and the second rotating shaft corresponding to one of the ventilation openings, and the shielding film is used to shield the ventilation opening;

A driving fan is rotatably arranged on the inner wall of the second box, and the driving fan is drivingly connected to the first rotating shaft;

Wherein, the dehumidification airflow can blow the driving fan and drive the first rotating shaft to rotate, so that the shielding film moves downward and exposes at least part of the ventilation opening.

In a preferred embodiment, the ventilation mechanism further includes a ventilation filter, and the ventilation filter cover is provided on the ventilation opening.

In a preferred embodiment, a display port and a transmission port are formed on the first box body. The first box body also has a transmission cover. An openable and closable cover of the transmission cover is provided on the transmission port. ;

The data collection module includes:

A sensor is arranged in the first accommodation space and located at the transmission port, and the sensor can be connected to an external device through the transmission port;

A display is connected to the sensor with a phase signal and is located at the display port. The display displays the information data collected by the sensor through the display port.

The characteristics and advantages of the present invention are:

The power load information data collector in the embodiment of the present invention is equipped with a water collection module and a dehumidification fan. When the outside weather is cold, the internal moisture will condense into water, and the water droplets formed by the condensation will flow into the water collection module. When the water storage reaches a certain amount, the dehumidification fan can start to work, generate airflow and blow the heat generated during the operation of the data acquisition module into the water collection module, so that the water storage in the water collection module evaporates, thereby preventing the data collector from Excessive moisture or liquid inside affects the accuracy of data collection.

Description of the drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below. Obviously, the drawings in the following description are only some embodiments of the present invention. For those of ordinary skill in the art, other drawings can also be obtained based on these drawings without exerting creative efforts.

Figure 1 shows a schematic diagram of the overall structure of the power load information data collector of the present invention.

Figure 2 shows an exploded schematic diagram of the overall structure of the power load information data collector of the present invention.

Figure 3 shows an exploded schematic structural diagram of the water collection box of the electric power load information data collector of the present invention.

Figure 4 shows a schematic diagram of the water collection mechanism of the power load information data collector of the present invention.

Figure 5 shows a schematic diagram of the heat conduction mechanism of the power load information data collector of the present invention.

Figure 6 shows a schematic diagram of the ventilation mechanism of the power load information data collector of the present invention.

Figure 7 shows a schematic diagram of the shielding film of the power load information data collector of the present invention.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, rather than all the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention. It should be noted that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is said to be "connected" to another element, it can be directly connected to the other element or there may also be intervening elements present. The terms "installation", "connection" and "connection" should be understood in a broad sense. For example, it can be a mechanical connection or an electrical connection, or it can be an internal connection between two components. It can be a direct connection or an indirect connection through an intermediate medium. For those of ordinary skill in the art, the specific meanings of the above terms can be understood according to specific circumstances. The terms "vertical", "horizontal", "upper", "lower", "left", "right" and similar expressions used herein are for illustrative purposes only and do not represent the only implementation manner.

Referring to Figures 1 and 2, an embodiment of the present invention provides a power load information data collector, which includes a collection unit 1 and a dehumidification unit 2. The collection unit 1 includes a data collection module, and the dehumidification unit 2 includes a water collection module 22 and a dehumidification unit 2. There is at least one dehumidification fan 23 . The dehumidification fan 23 is arranged above the water collection module 22 . The dehumidification fan 23 is used to blow the heat generated by the data acquisition module into the water collection module 22 .

In order to further explain the power load information data collector according to the embodiment of the present invention, its specific structure and connection relationship will be further described below, where:

In a preferred embodiment, the collection unit 1 includes a first box 11, a first accommodation space 111 is formed on the upper part of the first box 11, and the data acquisition module is arranged in the first accommodation space 111; the dehumidification unit 2 includes a first accommodation space 111. Two boxes 21, the second box 21 is formed with a second accommodation space 211, the water collection module 22 is arranged in the second accommodation space 211, and the dehumidification fan 23 is arranged at the upper end of the second box 21; wherein, the first box 11 The cover is provided on the second box body 21, and the first accommodating space 111 and the second accommodating space 211 are connected, so that the heat generated by the data acquisition module can enter the second accommodating space 211.

Please refer to FIGS. 3 and 4 together. In a preferred embodiment, the water collecting module 22 includes a water collecting box 221 and at least one water collecting mechanism 3 . The connection between the water collecting box 221 and the first box 11 is The lower parts are arranged to fit together, and a third accommodation space 222 is formed inside the water collection box 221. The water collection mechanism 3 is arranged in the third accommodation space 222; the water collection mechanism 3 includes: a condensation plate 31, which is fixedly connected to the water collection box. On the inner wall of the body 221, a movable groove 311 is formed in the middle of the condensation fin 31; the upper edge of the water collection bucket 32 is arranged in close contact with the condensation fin 31; the contact piece 33 is fixedly connected to the water collection hopper 32, and the contact piece 33 is fixedly connected to the water collection bucket 32. The water collecting bucket 32 is located on both sides of the condensation plate 31; the first elastic member 35 has its two ends connected to the lower end of the contact member 33 and the bottom of the water collection box 221 respectively. The first elastic member 35 is used to support the contact member. 33 and water collecting bucket 32; at least one touch switch 34 is provided on the inner wall of the water collecting box 221, and the touch switch 34 is used to control the dehumidification fan 23; among them, the water collecting bucket 32 and the touching piece 33 can move along the The groove 311 moves up and down, and the touch member 33 can touch the touch switch 34 to start or stop the dehumidification fan 23. Specifically, the first elastic member 35 may be a spring.

In a preferred embodiment, the number of dehumidification fans 23 is multiple, and the plurality of dehumidification fans 23 are arranged side by side on the upper end of the second box 21 . The number of touch switches 34 is the same as the number of dehumidification fans 23 . The touch switches 34 are arranged in parallel on the inner wall of the water collection box 221 along the up and down direction, and the plurality of touch switches 34 respectively control a plurality of dehumidification fans 23.

Please refer to Figure 5 as well. In a preferred embodiment, the dehumidification unit 2 includes a heat conduction mechanism 4, which is disposed on the water collection box 221; the heat conduction mechanism 4 includes: a heat conduction grille 41 with a plurality of Thermal conductive plates 411 are arranged side by side; the thermal conductive cylinder 42 is formed by extending downward from the thermal conductive grille 41. The thermal conductive cylinder 42 extends into the water collecting box 221. The lower end of the thermal conductive cylinder 42 is formed with a plurality of air outlets 421 distributed along the circumferential direction. ; Thermal conductive cover 43 is located at the lower end of the heat conductive cylinder 42. The periphery of the thermal conductive cover 43 extends upward to form a shielding portion. The shielding portion is used to block multiple air outlets 421; the support frame 44 is fixedly connected in the thermal conductive cylinder 42. , the heat-conducting cover 43 is movably connected to the support frame 44 through the second elastic member 45; wherein, the dehumidifying airflow formed by the dehumidifying fan 23 can pass through the heat-conducting grille 41 and enter the heat-conducting cylinder 42, and the dehumidifying airflow can blow the heat-conducting cover. The plate 43 moves downward to expose at least part of the air outlet holes 421, and the dehumidified air flow can enter the water collecting box 221 through the air outlet holes 421. Specifically, the second elastic member 45 may be a spring or an elastic cord.

In a preferred embodiment, the support frame 44 has an annular portion and a connecting portion. The connecting portion extends radially outward from the annular portion to the inner wall of the heat conductive barrel 42 so that the support frame 44 is fixedly connected in the heat conductive barrel 42 , both ends of the second elastic member 45 are respectively connected to the annular portion and the thermally conductive cover 43; the thermally conductive mechanism 4 also includes a limiting shaft 46, the limiting shaft 46 is fixedly connected to the thermally conductive cover 43, and passes through the annular The upper end of the limiting shaft 46 is formed with a plurality of limiting portions 461, and the limiting portions 461 can be locked on the upper end of the annular portion, so that the limiting shaft 46 limits the range of downward movement of the thermally conductive cover plate 43.

In a preferred embodiment, the heat-conducting plate 411 is inclined from top to bottom in the middle of the heat-conducting grille 41 so that the dehumidified air flow enters the heat-conducting cylinder 42 .

Please refer to Figure 6 as well. In a preferred embodiment, ventilation openings 212 are formed on both sides of the second box 21; the dehumidification unit 2 includes a ventilation mechanism 5, and the ventilation mechanism 5 is disposed in the second accommodation space 211. , and is located above the heat conduction mechanism 4; the ventilation mechanism 5 includes: a first rotating shaft 51, corresponding to the lower ends of the ventilation openings 212 on both sides of the second box 21; a second rotating shaft 52, corresponding to the second box 21 The upper ends of the vents 212 on both sides; the shielding film 53, both ends of which are respectively connected to the corresponding first rotating shaft 51 and the second rotating shaft 52 at a vent 212, the shielding film 53 is used to shield the vent 212; the driving fan 54 , is rotatably arranged on the inner wall of the second box 21, and the driving fan 54 is connected to the first rotating shaft 51; wherein, the dehumidifying air flow can blow the driving fan 54 and drive the first rotating shaft 51 to rotate, so that the shielding film 53 Move downward and expose at least part of the vent 212 . Specifically, the driving fan 54 can be connected to the first pulley 541 , and the first rotating shaft 51 can be connected to the second pulley 542 , so that the driving fan 54 can drive the first rotating shaft 51 to rotate through the belt 543 . Please refer to Figure 7 as well. The shielding film 53 can have a shielding section 531 and a ventilation section 532. The ventilation section 532 of the shielding film 53 can be wrapped around the second rotating shaft 52. When the first rotating shaft 51 rotates, the shielding film 53 can The shielding section 531 can be wound around the first rotating shaft 51 , and the ventilation section 532 of the shielding film 53 is pulled downward to expose the ventilation opening 212 . The second rotating shaft 52 can be designed as an elastic rotary structure. After the dehumidification fan 23 stops working, the second rotating shaft 52 can rebound and drive the ventilation section 532 of the shielding film 53 to rewind around the second rotating shaft 52 and make the shielding film 53 The blocking section 531 blocks the vent 212 again.

Please also refer to FIG. 6 . In a preferred embodiment, the ventilation mechanism 5 further includes a ventilation filter 55 , and the ventilation filter 55 is covered on the ventilation opening 212 .

Please refer to Figure 1. In a preferred embodiment, a display port 112 and a transmission port are formed on the first box body 11. The first box body 11 also has a transmission cover 113. The transmission cover 113 can be opened and closed. The cover is provided on the transmission port; the data acquisition module includes: a sensor, which is arranged in the first accommodation space 111 and is located at the transmission port. The sensor can be connected to an external device through the transmission port; a display is connected to the sensor in phase and is located at the display port. At 112, the display displays the information data collected by the sensor through the display port 112. Specifically, the transmission cover 113 is rotatably installed at the transmission port through a rotating shaft, so that the cover can be movable on the transmission port.

Based on the above structural description, the power load information data collector of the embodiment of the present invention has the following beneficial effects:

1. The power load information data collector in the embodiment of the present invention is equipped with a water collection module 22 and a dehumidification fan 23. When the outside weather is cold, the internal moisture will condense into water, and the water droplets formed by the condensation will flow into the water collection. In the module 22, when the stored water reaches a certain amount, the dehumidification fan 23 can start to work, generate airflow and blow the heat generated during the operation of the data acquisition module into the water collection module 22, so that the water stored in the water collection module 22 can be dehumidified. Water evaporates, thereby preventing excessive moisture or excess liquid inside the data collector from affecting the accuracy of data collection.

2. The water collection module 22 of the embodiment of the present invention includes a water collection box 221 and a water collection mechanism 3. The condensation plate 31 of the water collection mechanism 3 is connected to the water collection box 221, and the water collection box 221 is connected to the first box. The lower part of the body 11 is in contact with each other, making it easier for the condensation fin 31 to conduct heat with the outside world, so that the temperature of the condensation fin 31 is close to the outside world and is significantly lower than the temperature inside the data collector. Therefore, the moisture in the data collector will be the greatest. Water is first condensed on the condensing plate 31 instead of condensing on the circuit of the data acquisition module, effectively preventing the circuit from being short-circuited by water.

3. The water droplets condensed on the condensation plate 31 will flow into the water collecting bucket 32 through the upper edge of the water collecting bucket 32 . As the amount of water in the water collecting bucket 32 increases and the weight increases, the water collecting bucket 32 will drive the touch piece 33 to move downward together. When the touch piece 33 touches the touch switch 34, the dehumidification fan 23 can be triggered. When working, the hot air from above is blown into the water collecting box 221. Furthermore, when there is too much water in the water collecting bucket 32, the touch member 33 will further move down and trigger more touch switches 34, thereby causing more dehumidification fans 23 to work, increasing the volume of hot air, and accelerating the evaporation of water. speed.

4. The water collection module 22 in the embodiment of the present invention is also provided with a heat conduction mechanism 4. The heat conduction grille 41 of the heat conduction mechanism 4 can guide hot air into the water collection box 221, reducing the waste of hot air escaping. The heat conduction cylinder 42 of the heat conduction mechanism 4 extends into the water collection box 221 to further reduce the waste of hot air. A plurality of air outlets 421 are provided on the lower side of the heat conduction cylinder 42 to allow hot air to flow into the water collection box 221 evenly. A heat conductive cover 43 that can be elastically opened and closed is provided under the heat conductive cylinder 42. When the dehumidification fan 23 is working, it is blown open by the dehumidification airflow to expose the air outlet 421. When the dehumidification fan 23 stops working, the heat conductive cover 43 can cover the Cover and block the air outlet 421 to prevent moisture gradually generated in the water collection box 221 from flowing upward into the data acquisition module.

5. The dehumidification unit 2 of the embodiment of the present invention also includes a ventilation mechanism 5 provided above the heat conduction mechanism 4. The shielding film 53 of the ventilation mechanism 5 can generally block the vents 212 on both sides of the second box 21 to reduce the risk of Dust or small insects invade the second box 21, and when the dehumidification fan 23 is working, the dehumidification airflow can blow the driving fan 54 and drive the first rotating shaft 51 to rotate, so that the shielding film 53 moves down to expose the vent 212. The outside cold air flow enters the second box 21 under the action of air pressure, which lowers the temperature inside the second box 21 and reduces the temperature difference between the inside and outside, thereby reducing moisture and preventing excessive humidity in the data collector.

The above are only a few embodiments of the present invention. Those skilled in the art can make various changes or modifications to the embodiments of the present invention based on the disclosure of the application documents without departing from the spirit and scope of the present invention. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the technical field to which this application belongs. The terminology used herein in the description of the application is for the purpose of describing specific embodiments only and is not intended to limit the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Claims (8)

1. A power load information data collector, characterized in that it includes a collection unit and a dehumidification unit. The collection unit includes a data collection module. The dehumidification unit includes a water collection module and at least one dehumidification fan. The dehumidification fan is configured Above the water collection module, the dehumidification fan is used to blow the heat generated by the data acquisition module into the water collection module; The collection unit includes a first box, the dehumidification unit includes a second box, the second box is formed with a second accommodation space, the water collection module is arranged in the second accommodation space, and the A dehumidification fan is provided at the upper end of the second box; The water collecting module includes a water collecting box and at least one water collecting mechanism. The water collecting box is arranged in contact with the lower part of the first box. A third accommodation is formed inside the water collecting box. space, the water collection mechanism is arranged in the third accommodation space; The dehumidification unit includes a heat conduction mechanism, and the heat conduction mechanism is provided on the water collection box; The water collection mechanism includes: The condensation fin is fixedly connected to the inner wall of the water collecting box, and a movable groove is formed in the middle of the condensation fin; The upper edge of the water collecting bucket is arranged in close contact with the condensation plate; The contact piece is fixedly connected to the water collecting bucket, and the touching piece and the water collecting bucket are respectively located on both sides of the condensation plate; A first elastic member, both ends of which are respectively connected to the lower end of the contact member and the bottom of the water collection box, and the first elastic member is used to support the contact member and the water collection bucket; At least one touch switch is provided on the inner wall of the water collection box, and the touch switch is used to control the dehumidification fan; Wherein, the water collecting bucket and the contact piece can move up and down along the movable groove, and the contact piece can touch the touch switch to start or stop the rotation of the dehumidification fan; Ventilation openings are formed on both sides of the second box; The dehumidification unit includes a ventilation mechanism, which is arranged in the second accommodation space and located above the heat conduction mechanism; The ventilation mechanism includes: A first rotating shaft corresponding to the lower ends of the ventilation openings provided on both sides of the second box; a second rotating shaft corresponding to the upper ends of the ventilation openings provided on both sides of the second box; A shielding film with two ends respectively connected to the first rotating shaft and the second rotating shaft corresponding to one of the ventilation openings, and the shielding film is used to shield the ventilation opening; A driving fan is rotatably arranged on the inner wall of the second box, and the driving fan is drivingly connected to the first rotating shaft; Wherein, the dehumidification fan can form a dehumidification airflow, and the dehumidification airflow can blow the driving fan and drive the first rotating shaft to rotate, so that the shielding film moves downward and exposes at least part of the ventilation opening. 2. The power load information data collector according to claim 1, wherein a first accommodation space is formed on the upper part of the first box, and the data collection module is arranged in the first accommodation space; Wherein, the first box cover is provided on the second box, and the first accommodating space and the second accommodating space are connected, so that the heat generated by the data acquisition module can enter the third accommodating space. 2. Within the accommodation space. 3. The power load information data collector according to claim 1, characterized in that the number of the dehumidification fans is multiple, and the plurality of dehumidification fans are arranged side by side at the upper end of the second box, and the The number of touch switches is the same as the number of dehumidification fans. A plurality of the touch switches are arranged side by side on the inner wall of the water collecting box along the up and down direction. The plurality of touch switches respectively control multiple corresponding ones. The dehumidification fan. 4. The electric power load information data collector according to claim 1, wherein the heat conduction mechanism includes: Thermal conductive grille has multiple thermal conductive plates arranged side by side; A heat-conducting tube is formed by extending downward from the heat-conducting grille. The heat-conducting tube extends into the water collection box. A plurality of air outlets are formed on the lower end of the heat-conducting tube along the circumferential direction; A thermally conductive cover plate is provided at the lower end of the thermally conductive cylinder, and the peripheral edge of the thermally conductive cover plate extends upward to form a shielding portion, and the shielding portion is used to shield a plurality of the air outlets; A support frame is fixedly connected in the heat-conducting cylinder, and the heat-conducting cover is movably connected to the support frame through a second elastic member; Wherein, the dehumidification airflow formed by the dehumidification fan can pass through the heat conduction grille and enter the heat conduction cylinder, and the dehumidification airflow can blow the heat conduction cover plate to move downward to expose at least part of the heat conduction cover. An air outlet through which the dehumidified airflow can enter the water collecting box. 5. The power load information data collector according to claim 4, wherein the support frame has an annular portion and a connecting portion, and the connecting portion extends radially outward from the annular portion to the on the inner wall of the heat-conducting cylinder, so that the support frame is fixedly connected in the heat-conducting cylinder, and the two ends of the second elastic member are respectively connected to the annular portion and the heat-conducting cover plate; The thermal conductive mechanism also includes a limiting shaft, which is fixedly connected to the thermally conductive cover plate and passes through the annular portion. A plurality of limiting portions are formed on the upper end of the limiting shaft. The limiting portion can be locked on the upper end of the annular portion, so that the limiting shaft limits the downward movement range of the thermally conductive cover plate. 6. The power load information data collector according to claim 4, wherein the heat conduction plate is tilted from top to bottom toward the middle of the heat conduction grille, so that the dehumidification airflow enters the heat conduction grille. inside the cylinder. 7. The power load information data collector according to claim 1, wherein the ventilation mechanism further includes a ventilation filter, and the ventilation filter cover is provided on the ventilation opening. 8. The power load information data collector according to claim 2, wherein a display port and a transmission port are formed on the first box body, and the first box body also has a transmission cover body, and the transmission port body is A cover that can be opened and closed is provided on the transmission port; The data collection module includes: A sensor is arranged in the first accommodation space and located at the transmission port, and the sensor can be connected to an external device through the transmission port; A display is connected to the sensor with a phase signal and is located at the display port. The display displays the information data collected by the sensor through the display port.