CN119042081A - Unmanned on duty electricity distribution room solar power system - Google Patents

Abstract

The application discloses a solar power generation device of an unattended power distribution room, which relates to the technical field of solar power generation and comprises a support assembly, wherein the support assembly comprises a base, a support, support frames and connecting plates, the support is cylindrical, the axis of the support is perpendicular to the ground, the support is fixed on the base, the connecting plates are consistent with the support frames in number and correspond to each other one by one, the plurality of connecting plates are annularly fixed on the side wall of the support, the support frames are fixed on one side of the connecting plates far away from the support frames, an air inlet channel is formed between two adjacent support frames, the length of a heating plate can be gradually shortened from top to bottom, the air inlet interval between the plurality of heating plates and the support frames is gradually increased, when air in the air inlet interval passes, the opening is gradually reduced, the air flowing inside can be accelerated, the air can be accelerated, the rotating speed of a power generation fan blade can be driven to be accelerated, and the power generation efficiency is improved.

Description

Unmanned on duty electricity distribution room solar power system

Technical Field

The invention relates to the technical field of solar power generation, in particular to a solar power generation device of an unattended power distribution room.

Background

The unattended power distribution room is a modern power distribution room operation management mode, normal operation and unattended operation of the power distribution room are achieved through advanced technical equipment and man-machine cooperation, when the unattended power distribution room is operated, a large amount of power is needed to be used as a support, the operation cost is high, solar energy can be used for power generation, and the operation cost of the unattended power distribution room is reduced.

Solar power generation is a power generation mode that converts solar radiation energy into electrical energy through water or other mediums and devices. Solar power generation is a clean renewable energy source, most of energy required by human beings is directly or indirectly from the sun, and in daily life, the solar energy can be utilized, so that the waste of resources is avoided.

The solar power generation device provided by the grant publication CN113614368B is used for generating electricity by generating an ascending air current by heating with sunlight and turning a fan by the ascending air current, thereby generating electricity in an environment-friendly manner. When sunlight irradiates the heating plates, the heating plates absorb heat and heat, the heat heats the air between the heating plates, the hot air rises to generate rising air flow, the rising air flow is collected in the flow passage, and the rising air flow gradually rises through the flow passage to drive the fan to rotate so as to generate electricity, so that the solar power generation device for generating electricity in an environment-friendly way is provided.

The device has the advantages that in the using process, rising air flows are gathered in the flow channel and gradually rise to drive the fan to rotate for power generation, and when the rising air flows are discharged through the flow channel, the flow speed of the rising air flows obtained by heating by the heating plate is low, so that the rotating speed of the fan is low.

Disclosure of Invention

According to the embodiment of the application, by providing the solar power generation device of the unattended power distribution room, the problems that rising airflow is concentrated in a runner and gradually rises to drive a fan to rotate for power generation in the prior art, the rising airflow is heated by a heating plate independently when being discharged through the runner, so that the rotating speed of the fan is low, the length of the heating plate is gradually shortened from top to bottom, the air inlet intervals between a plurality of heating plates and a bracket are gradually increased, the openings are gradually reduced when the air in the air inlet intervals passes, the air flowing in the air inlet intervals can be accelerated, the air is accelerated, the rotating speed of a power generation fan blade can be driven to be accelerated, and the power generation efficiency is improved.

The embodiment of the application provides a solar power generation device of an unattended power distribution room, which comprises a support assembly, wherein the support assembly comprises a base, a bracket, a support frame and a connecting plate;

The support is cylindrical, the axis of the support is perpendicular to the ground, the support is fixed on the base, the number of the connecting plates is consistent with that of the supporting frames, the connecting plates are in one-to-one correspondence, a plurality of connecting plates are annularly fixed on the side wall of the support, and the supporting frames are fixed on one side of the connecting plates far away from the support;

an air inlet channel is formed between two adjacent support frames;

The air inlet device comprises a plurality of supporting frames, and is characterized by further comprising heating assemblies, wherein the number of the heating assemblies is consistent with the number of air inlet intervals formed among the plurality of supporting frames and corresponds to the number of the air inlet intervals one by one;

the heating assembly comprises a plurality of heating plates, wherein the heating plates are uniformly distributed at intervals along the axial direction of the support, and two ends of each heating plate are respectively fixed on the side wall of the support frame forming the air inlet channel;

The surface of the heating plate is black;

an air inlet interval is reserved on one side of the heating plate, which is close to the bracket;

the heating plates are obliquely arranged, the oblique direction of the heating plates is the length direction of the heating plates, and the length of the heating plates is gradually reduced from top to bottom;

The height of one end of the heating plate far away from the support is lower than that of one end of the heating plate close to the support, and the air inlet interval between the heating plates and the support is gradually increased from bottom to top.

As an improvement, the support frame is a triangular prism, the length direction of the support frame is perpendicular to the ground, and one side of the connecting plate, which is far away from the support frame, is fixed on one side edge of the support frame.

As an improvement, the support component further comprises a guide cover and power generation fan blades;

The guide cover is fixed on the connecting plate, the guide cover is arc-shaped, the guide cover is provided with power generation fan blades, the support is internally provided with a generator, and the rotating shaft of the power generation fan blades is fixed on the generator.

As an improvement, the heating assembly further comprises an air bag;

the upper side surface and the lower side surface of the heating plate are respectively provided with an air bag;

the supporting component further comprises an air pump and a conveying pipe I;

The support frame is hollow, and the number of the air pumps is the same as that of the air bags and corresponds to the air bags one by one;

the air pump is fixed in the support frame, conveyer pipe one end is fixed at the air pump output, the one end that the air pump was kept away from to the conveyer pipe passes support frame lateral wall and gasbag intercommunication.

As an improvement, the heating assembly further comprises a rotating channel and a traction block;

The upper side surface and the lower side surface of the heating plate are respectively provided with a rotary channel, the rotary channels are U-shaped, the U-shaped opening of the rotary channel above the heating plate faces upwards, and the U-shaped opening of the rotary channel below the heating plate faces downwards;

one side, far away from the U-shaped opening, of the rotating channel is fixed with an electric sliding table;

the air bag is annular, the air bag is sleeved in the rotary channel, the air bag is provided with a traction block, and the traction block is fixed on a sliding block of the electric sliding table.

As an improvement, the length direction of the rotating channel is parallel to the width direction of the heating plate, and the length of the rotating channel is consistent with the width of the heating plate;

the length direction of the electric sliding table is parallel to the length direction of the heating plate;

the length direction of the traction block is parallel to the length direction of the rotating channel, and the length of the traction block is consistent with the length of the rotating channel.

As an improvement, in the unexpanded state of the air bag, the length of the air bag is consistent with the length of the rotating channel;

when the traction block is positioned at one end of the rotating channel far away from the bracket, one end of the conveying pipe far away from the air pump is fixed at one end of the air bag close to the bracket.

As an improvement, the first conveying pipe is a telescopic pipe;

the gap between the opening of the rotating channel and the two ends of the heating plate in the length direction is 1-2 cm;

The air bag is made of black butyl rubber.

As an improvement, the heating component further comprises an air jet pipe and a conveying pipe II;

The number of the air ejector pipes is consistent with that of the air bags and corresponds to that of the air bags one by one,

The air ejector tube is fixed on the air bag;

One end of the second conveying pipe is fixed at the output end of the air pump, and one end of the second conveying pipe far away from the air pump penetrates through the side wall of the support frame to be communicated with the air ejector pipe;

The air pump is provided with two output ends which are controlled independently, and the second conveying pipe and the first conveying pipe are respectively fixed on the two output ends of the air pump;

the air ejector is provided with an air ejector;

the second conveying pipe is a telescopic pipe.

As an improvement, the length direction of the air ejector tube is parallel to the length direction of the air bag, and the length of the air ejector tube is consistent with the length of the air bag;

when the traction block is positioned at one end of the rotating channel far away from the bracket, the air ejector tube is positioned at one end of the air bag close to the bracket.

One or more technical solutions provided in the embodiments of the present application at least have the following technical effects or advantages:

firstly, the length of the heating plate is gradually shortened from top to bottom, so that the air inlet intervals between the heating plates and the brackets are gradually increased from bottom to top;

Secondly, the safety of the device in use is improved, and sundries in the air inlet channel are blocked from being influenced by ascending air flow through the expansion of the air bag, so that the device can automatically fall off; the expansion of the air bag can close an air inlet channel towards one side of the wind direction under the condition of larger external wind force, so that larger wind force is prevented, a large amount of sundries are blown into the device to cause blockage and damage in the device;

Thirdly, through the rotation of the air bag, deep leaves, branches or plastic bags can be pushed out through a rotary conveying mode, so that the cleaning effect on sundries is improved, meanwhile, in the process that the air bag rotates, dust attached to the surface of the air bag can be scraped by the rotating channel for cleaning, the cleaning effect on the air bag is improved, and the heat absorption effect of the air bag is guaranteed;

Fourthly, fixing an air jet pipe at one end of the air bag, moving the air jet pipe to the other side in the rotating process of the air bag, blowing out leaves, branches or plastic bags faster through an air jet mode to clean, improving the cleaning effect on the leaves, branches or plastic bags, cooling the surface of the air bag above or below through the air jet mode through the rotation of the air bag to enable the plastic bag with a melting phenomenon to be quickly solidified, and rotating the air bag after solidification, namely, quickly removing the air bag through a rotating channel to prevent heat absorption effect from deteriorating due to the fact that high temperature cannot be removed, and blowing down dust attached to the surface of the air bag by relative air jet between the air bags to improve the cleaning effect.

Drawings

FIG. 1 is a front cross-sectional view of an unattended power distribution room solar power generation device of the invention;

FIG. 2 is a top view of the support frame and the connection plate of the solar power generation device of the unattended power distribution room;

FIG. 3 is a schematic diagram of the installation of an air bag of an unmanned power distribution room solar power generation device according to the invention;

FIG. 4 is an air bag expansion state diagram of an unattended power distribution room solar power generation device according to the invention;

FIG. 5 is a schematic diagram of the installation of an air pump of the solar power generation device of the unattended power distribution room;

FIG. 6 is an enlarged view of the structure A in FIG. 5 of an unattended power distribution room solar power generation device according to the invention;

FIG. 7 is a top view of a rotating aisle of an unattended power distribution room solar power generation device according to the invention;

FIG. 8 is a schematic diagram of a rotating tunnel of an unattended power distribution room solar power generation device according to the invention;

FIG. 9 is a schematic diagram showing the rotation state of an air bag of the solar power generation device of the unattended power distribution room;

FIG. 10 is a schematic diagram of the installation of gas nozzles of an unmanned power distribution room solar power generation device according to the present invention;

FIG. 11 is a schematic diagram of the change of the position of an air bag rotary air ejector of the solar power generation device of the unattended power distribution room;

fig. 12 is a schematic view showing a single air bag rotation state of the solar power generation device of the unattended power distribution room.

100 Parts of a supporting component, 110 parts of a base, 120 parts of a bracket, 130 parts of a guide cover, 140 parts of a power generation fan blade, 150 parts of a supporting frame, 160 parts of a connecting plate, 170 parts of an air pump, 180 parts of a conveying pipe I, 190 parts of a conveying pipe II;

200. heating component 210, heating plate 211, rotating channel 220, air bag 230, traction block 240 and air jet pipe.

Detailed Description

In order that the application may be readily understood, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, in which, however, the application may be embodied in many different forms and is not limited to the embodiments described herein, but is instead provided for the purpose of providing a more thorough understanding of the present disclosure.

It should be noted that the terms "vertical", "horizontal", "upper", "lower", "left", "right", and the like are used herein for illustrative purposes only and do not represent the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, the terms used herein in this description of the invention are used for the purpose of describing particular embodiments only and are not intended to be limiting of the invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

1-2, The solar power generation device of the unattended power distribution room comprises a support assembly 100, wherein the support assembly 100 comprises a base 110, a bracket 120, a support frame 150 and a connecting plate 160;

The support 120 is cylindrical, the axis of the support 120 is perpendicular to the ground, the support 120 is fixed on the base 110, the number of the connecting plates 160 is the same as that of the support frames 150, the connecting plates 160 are in one-to-one correspondence, the plurality of connecting plates 160 are annularly fixed on the side wall of the support 120, and the support frames 150 are fixed on one side of the connecting plates 160 far away from the support 120;

an air inlet channel is formed between two adjacent support frames 150;

The number of the heating assemblies 200 is consistent with that of the air inlet intervals formed among the plurality of support frames 150, and the heating assemblies 200 are in one-to-one correspondence with the air inlet intervals;

the heating assembly 200 includes a plurality of heating plates 210, wherein the plurality of heating plates 210 are uniformly spaced along the axis direction of the bracket 120, and two ends of the heating plates 210 are respectively fixed on the side wall of the supporting frame 150 forming the air inlet channel;

the surface of the heating plate 210 is black;

An air inlet interval is reserved on one side of the heating plate 210 close to the bracket 120;

The heating plate 210 is obliquely arranged, the oblique direction of the heating plate 210 is the length direction of the heating plate 210, and the length of the heating plate 210 is gradually reduced from top to bottom;

the height of the end of the heating plate 210 far away from the bracket 120 is lower than that of the end of the heating plate 210 near the bracket 120, and the air inlet intervals between the plurality of heating plates 210 and the bracket 120 are gradually increased from bottom to top;

the support 150 is a triangular prism, the length direction of the support 150 is perpendicular to the ground, and one side of the connecting plate 160 away from the bracket 120 is fixed on one side edge of the support 150;

the support assembly 100 further includes a guide housing 130 and a power generation blade 140;

the guide cover 130 is fixed on the connecting plate 160, the guide cover 130 is arc-shaped, the guide cover 130 is provided with power generation fan blades 140, the bracket 120 is internally provided with a power generator, and the rotating shaft of the power generation fan blades 140 is fixed on the power generator.

In the use process, the heating plates 210 are irradiated by solar energy, the temperature rises, so that the air between the heating plates 210 is heated, ascending air flow is generated, the ascending air flow is gathered in the air inlet interval and gradually rises, meanwhile, the air also enters into the gaps between the heating plates 210, gradually rises through the gaps between the heating plates 210, and drives the power generation fan blades 140 to rotate, so that the power generation fan blades 140 rotate to generate power.

The length of the heating plate 210 is gradually shortened from top to bottom, so that the air inlet intervals between the heating plates 210 and the bracket 120 are gradually increased from bottom to top, and when the air in the air inlet intervals passes through, the openings are gradually reduced, so that the air flowing in the air inlet intervals can be accelerated, the air can be accelerated, the rotation speed of the power generation fan blades 140 can be driven to be accelerated, and the power generation efficiency is improved.

In the second embodiment, when the air is heated by the heating plate 210 to generate ascending air flow to generate electricity, but when the air conditioner is used, the air inlet amount cannot be adjusted, and under the condition of large external wind force, the air inlet amount is influenced by the wind force, and leaves, branches or plastic bags are intercepted at one side of the heating plate 210 far away from the bracket 120, so that the sun cannot irradiate on the heating plate 210, and in the process of gradually increasing the internal temperature, the intercepted leaves or plastic bags are contacted for a long time, so that fire is easily caused, thereby improving the scheme of the first embodiment, as shown in fig. 3-6:

the heating assembly 200 further includes a balloon 220;

The upper side and the lower side of the heating plate 210 are respectively provided with an air bag 220;

the support assembly 100 further includes an air pump 170 and a delivery tube 180;

the support frame 150 is hollow, and the number of the air pumps 170 is the same as the number of the air bags 220 and corresponds to one another;

the air pump 170 is fixed in the support frame 150, one end of the first conveying pipe 180 is fixed at the output end of the air pump 170, and one end of the first conveying pipe 180, which is far away from the air pump 170, passes through the side wall of the support frame 150 and is communicated with the air bag 220;

the electricity required by the operation of the air pump 170 is generated by the power generation fan blades 140.

In the use process, when the heating plate 210 is far away from one side of the bracket 120 and is used for intercepting leaves, branches or plastic bags, the air bags 220 positioned in the air inlet channel are inflated to seal, sundries are not influenced by ascending air flow and can automatically fall off, meanwhile, the inflation amounts of the air bags 220 at different positions are different, the air inflow of different positions can be controlled, the air flows in the air bags can reach the optimal state and continuously rise, the flow rate of the air is controlled, unstable influence on the rotation of the power generation fan blades 140 caused by overlarge wind force is prevented, under the condition that the external wind force is large, the air inlet channel towards one side of the wind direction is closed, the wind force is prevented from being large, a large amount of sundries are blown into the device to cause blockage damage in the device, and the inflation of the air bags 220 can cause dust adhered to the surface of the air bags 220 to shake off.

The safety of the device in use is improved, sundries in the air inlet channel are blocked from being influenced by ascending air flow through the expansion of the air bag 220, the air inlet channel towards one side of the wind direction can be closed through the expansion of the air bag 220 under the condition of large external wind force, the large wind force is prevented from blowing a large amount of sundries into the device to cause blockage and damage in the device, the air bag 220 is expanded to different degrees, the amount of entering air can be controlled, unstable influence on rotation of the power generation fan blades 140 caused by excessive wind force is prevented, and dust attached to the surface of the air bag 220 can be vibrated down through the expansion of the air bag 220, so that the heating effect on air is improved.

In the third embodiment, when the air bag 220 is inflated, the air inlet channel is closed, so that the intercepted leaves or plastic bags can automatically fall, but in the process of inflating the air bag 220, as the leaves, branches or plastic bags enter the air inlet channel between the two heating plates 210, the leaves, branches or plastic bags can be clamped by the inflation of the air bag 220, so that the leaves, branches or plastic bags can not automatically fall, so that the scheme of the second embodiment is improved, as shown in fig. 7-9:

the heating assembly 200 further includes a rotating tunnel 211 and a traction block 230;

The upper side surface and the lower side surface of the heating plate 210 are respectively provided with a rotating channel 211, the rotating channels 211 are U-shaped, the U-shaped opening of the rotating channel 211 positioned above the heating plate 210 faces upwards, the U-shaped opening of the rotating channel 211 positioned below the heating plate 210 faces downwards, the length direction of the rotating channel 211 is parallel to the width direction of the heating plate 210, and the length of the rotating channel 211 is consistent with the width of the heating plate 210;

An electric sliding table is fixed on one side, far away from the U-shaped opening, of the rotating channel 211, and the length direction of the electric sliding table is parallel to the length direction of the heating plate 210;

the air bag 220 is annular, the air bag 220 is sleeved in the rotary channel 211, the air bag 220 is provided with a traction block 230, and the traction block 230 is fixed on a sliding block of the electric sliding table;

In the unexpanded state of the balloon 220, the length of the balloon 220 is consistent with the length of the rotation path 211;

The length direction of the traction block 230 is parallel to the length direction of the rotating channel 211, and the length of the traction block 230 is consistent with the length of the rotating channel 211;

when the traction block 230 is positioned at one end of the rotating channel 211 far away from the bracket 120, one end of the first conveying pipe 180 far away from the air pump 170 is fixed at one end of the air bag 220 near the bracket 120;

The first conveying pipe 180 is a telescopic pipe;

The opening of the rotating channel 211 is spaced 1-2 cm from the two ends of the heating plate 210 in the length direction;

the air bag 220 is made of black butyl rubber;

The electricity required by the operation of the electric sliding table is generated by the power generation fan blades 140.

After the air bag 220 is inflated, the air inlet channel is closed, the traction block 230 is driven to move towards one side close to the bracket 120 by the operation of the electric sliding table in the rotating channel 211, so that the air bag 220 rotates, the clamped leaves, branches or plastic bags are rotationally conveyed out in the rotating process, after the leaves, branches or plastic bags are not completely conveyed out by one rotation, the air bag 220 is deflated, the traction block 230 is reset by the driving of the electric sliding table, the air bag 220 is inflated again, the reciprocating operation is performed, the leaves, branches or plastic bags entering the air bag are conveyed out, and dust attached to the surface of the air bag 220 can be scraped by the rotating channel 211 in the rotating process of the air bag 220, so that the air bag is cleaned.

Through the rotation of the air bag 220, the deep leaves, branches or plastic bags can be pushed out through the mode of rotary conveying, the cleaning effect on sundries is improved, meanwhile, in the process that the air bag 220 rotates, dust attached to the surface of the air bag 220 can be scraped by the rotary channel 211, cleaning is carried out, the cleaning effect on the air bag 220 is improved, and the heat absorbing effect is guaranteed.

In the fourth embodiment, when the air bag 220 is used, leaves, branches or plastic bags in an air inlet channel are conveyed out through rotation of the air bag 220, but in a state of continuous high temperature, the plastic bags are easily melted when contacting the air bag 220 and are attached to the surface of the air bag 220, so that the plastic bags are adhered and hung on the air bag 220, and the scheme of the third embodiment is improved, as shown in fig. 5-6 and fig. 10-12:

The heating assembly 200 further comprises an air jet pipe 240 and a conveying pipe II 190;

The number of the air ejector tubes 240 is consistent with the number of the air bags 220, and the air ejector tubes 240 are in one-to-one correspondence, the length direction of the air ejector tubes 240 is parallel to the length direction of the air bags 220, and the length of the air ejector tubes 240 is consistent with the length of the air bags 220;

the gas nozzles 240 are fixed to the airbag 220;

When the traction block 230 is positioned at one end of the rotating channel 211 far away from the bracket 120, the air injection pipe 240 is positioned at one end of the air bag 220 near the bracket 120;

one end of the second conveying pipe 190 is fixed at the output end of the air pump 170, and one end of the second conveying pipe 190, which is far away from the air pump 170, passes through the side wall of the support frame 150 and is communicated with the air ejector pipe 240;

The air pump 170 has two output ends which are controlled independently, and the two conveying pipes 190 and 180 are respectively fixed on the two output ends of the air pump 170;

the gas nozzles 240 are provided with gas nozzles;

The second conveying pipe 190 is a telescopic pipe.

When the melted plastic bag is attached to the surface of the air bag 220, the air bag 220 on the opposite side can be rotated, in the rotating process, the conveying pipe II 190 supplies air to the air spraying pipe 240, so that the air spraying pipe 240 can spray air towards the air bag 220 attached with the melted plastic bag, the air bag 220 can be quickly cooled and solidified, after solidification, the air bag 220 can be quickly removed through the rotation channel 211, meanwhile, when dust on the surface of the air bag 220 needs to be cleaned, the air bag 220 above the heating plate 210 is not started, the air bag 220 below the heating plate 210 is started, dust on the surface of the air bag 220 above the heating plate 210 is blown off, and similarly, the air bag 220 below the heating plate 210 is not started, dust on the surface of the air bag 220 below the heating plate 210 is blown off, and when the air bag 220 clamps leaves, branches or plastic bags are conveyed out, the air spraying branches or the plastic bags can be moved to a more distant position through the air spraying pipe 240.

The air injection pipe 240 is fixed at one end of the air bag 220, the air injection pipe 240 is moved to the other side in the rotating process of the air bag 220, leaves, branches or plastic bags are blown out faster to clean in an air injection mode, the cleaning effect on the leaves, branches or plastic bags is improved, the plastic bags with melting phenomenon are cooled down on the surface of the air bag 220 above or below in an air injection mode through the rotation of the air bag 220, the plastic bags are quickly solidified, the air bag 220 can be quickly removed through the rotating channel 211 after solidification, the heat absorption effect is prevented from being worsened due to the fact that high temperature cannot be removed, and relative air injection between the air bags 220 can blow off dust attached to the surface of the air bag 220, so that the cleaning effect is improved.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The solar power generation device for the unattended power distribution room comprises a support assembly (100), wherein the support assembly (100) comprises a base (110), a bracket (120), a support frame (150) and a connecting plate (160);

The support (120) is cylindrical, the axis of the support (120) is perpendicular to the ground, the support (120) is fixed on the base (110), the number of the connecting plates (160) is consistent with that of the support frames (150) and corresponds to that of the connecting plates one by one, the plurality of the connecting plates (160) are annularly fixed on the side wall of the support (120), and the support frames (150) are fixed on one side, far away from the support (120), of the connecting plates (160);

an air inlet channel is formed between two adjacent supporting frames (150);

The device is characterized by further comprising heating assemblies (200), wherein the number of the heating assemblies (200) is consistent with that of air inlet intervals formed among the plurality of support frames (150), the heating assemblies (200) are in one-to-one correspondence with the air inlet intervals;

The heating assembly (200) comprises a plurality of heating plates (210), wherein the heating plates (210) are uniformly distributed at intervals along the axial direction of the bracket (120), and two ends of each heating plate (210) are respectively fixed on the side wall of the supporting frame (150) forming the air inlet channel;

The surface of the heating plate (210) is black;

an air inlet interval is reserved on one side of the heating plate (210) close to the bracket (120);

The heating plate (210) is obliquely arranged, the oblique direction of the heating plate (210) is the length direction of the heating plate (210), and the length of the heating plate (210) is gradually reduced from top to bottom;

the height of one end of the heating plate (210) far away from the bracket (120) is lower than that of one end of the heating plate (210) close to the bracket (120), and the air inlet intervals between the plurality of heating plates (210) and the bracket (120) are gradually increased from bottom to top.

2. The solar power generation device of an unattended power distribution room according to claim 1, wherein the support frame (150) is a triangular prism, the length direction of the support frame (150) is perpendicular to the ground, and one side of the connecting plate (160) away from the support frame (120) is fixed on one side edge of the support frame (150).

3. An unattended power distribution room solar power generation apparatus as claimed in claim 1, wherein the support assembly (100) further comprises a guide cover (130) and power generation blades (140);

The guide cover (130) is fixed on the connecting plate (160), the guide cover (130) is arc-shaped, the guide cover (130) is provided with power generation fan blades (140), the support (120) is internally provided with a power generator, and the rotating shaft of the power generation fan blades (140) is fixed on the power generator.

4. An unattended power distribution room solar power generation apparatus as claimed in claim 1, wherein the heating assembly (200) further comprises an airbag (220);

the upper side and the lower side of the heating plate (210) are respectively provided with an air bag (220);

the supporting component (100) further comprises an air pump (170) and a first conveying pipe (180);

the support frames (150) are hollow, and the number of the air pumps (170) is the same as that of the air bags (220) and corresponds to one air bag;

The air pump (170) is fixed in the support frame (150), one end of the first conveying pipe (180) is fixed at the output end of the air pump (170), and one end, far away from the air pump (170), of the first conveying pipe (180) is communicated with the air bag (220) through the side wall of the support frame (150).

5. An unattended power distribution room solar power generation apparatus as recited in claim 4, wherein the heating assembly (200) further comprises a rotating tunnel (211) and a traction block (230);

the upper side surface and the lower side surface of the heating plate (210) are respectively provided with a rotary channel (211), the rotary channels (211) are U-shaped, the U-shaped opening of the rotary channel (211) above the heating plate (210) faces upwards, and the U-shaped opening of the rotary channel (211) below the heating plate (210) faces downwards;

an electric sliding table is fixed on one side, far away from the U-shaped opening, of the rotating channel (211);

The air bag (220) is annular, the air bag (220) is sleeved in the rotary channel (211), the air bag (220) is provided with a traction block (230), and the traction block (230) is fixed on a sliding block of the electric sliding table.

6. An unattended power distribution room solar power generation apparatus as claimed in claim 5, wherein the length direction of the rotating duct (211) is parallel to the width direction of the heating plate (210), and the length of the rotating duct (211) is consistent with the width of the heating plate (210);

The length direction of the electric sliding table is parallel to the length direction of the heating plate (210);

the length direction of the traction block (230) is parallel to the length direction of the rotating channel (211), and the length of the traction block (230) is consistent with the length of the rotating channel (211).

7. An unattended power distribution room solar power generation apparatus as claimed in claim 5, wherein in an unexpanded state of the air bag (220), the length of the air bag (220) is consistent with the length of the rotating way (211);

When the traction block (230) is positioned at one end of the rotating channel (211) far away from the bracket (120), one end of the conveying pipe I (180) far away from the air pump (170) is fixed at one end of the air bag (220) near the bracket (120).

8. An unattended power distribution room solar power generation apparatus as claimed in claim 5, wherein the first conveying pipe (180) is a telescopic pipe;

the opening of the rotating channel (211) is spaced 1-2 cm away from the two ends of the heating plate (210) in the length direction;

The air bag (220) is made of black butyl rubber.

9. An unattended power distribution room solar power generation apparatus as recited in claim 5, wherein the heating assembly (200) further comprises an air lance (240) and a delivery pipe two (190);

the number of the air ejector pipes (240) is consistent with the number of the air bags (220) and corresponds to one,

The gas spraying pipe (240) is fixed on the air bag (220);

One end of the second conveying pipe (190) is fixed at the output end of the air pump (170), and one end, far away from the air pump (170), of the second conveying pipe (190) penetrates through the side wall of the support frame (150) to be communicated with the air ejector pipe (240);

The air pump (170) is provided with two output ends which are controlled independently, and the conveying pipe two (190) and the conveying pipe one (180) are respectively fixed on the two output ends of the air pump (170);

the gas spraying pipe (240) is provided with a gas spraying port;

and the second conveying pipe (190) is a telescopic pipe.

10. An unattended power distribution room solar power generation apparatus as claimed in claim 9, wherein the length direction of the gas injection pipe (240) is parallel to the length direction of the air bag (220), and the length of the gas injection pipe (240) is consistent with the length of the air bag (220);

When the traction block (230) is positioned at one end of the rotating channel (211) far away from the bracket (120), the air injection pipe (240) is positioned at one end of the air bag (220) close to the bracket (120).