CN112217271A - Intelligent power supply system of sunshine room - Google Patents

Abstract

The invention discloses an intelligent power supply system of a sunlight room, which comprises a sunlight room main body; the main control system is arranged in the sunlight room main body; the power storage unit and the power utilization unit are connected with the master control system; the solar power generation unit is laid outside the sunlight room main body; the solar power generation unit is connected with the master control system, is connected with the power storage unit through the master control system to charge the power storage unit, and simultaneously supplies power to the master control system; through master control system, the electricity generation input unit, the power supply output unit, the voltage monitoring unit, storage battery, battery management module, electricity generation management module and solar photovoltaic board isotructure, constitute the intelligent power supply system who is used for the sunshine room, generate electricity through solar energy, and store the electric energy through the battery, set up monitoring unit simultaneously and monitor each power generation process, constitute the intelligent power supply system who is used for the sunshine room, the power supply mode problem and the potential safety hazard problem in sunshine room among the prior art have been solved.

Description

Intelligent power supply system of sunshine room

Technical Field

The invention belongs to the technical field of power supply systems of sunlight rooms, and particularly relates to an intelligent power supply system of a sunlight room.

Background

Sunlight rooms are also known as glasshouses. The sunlight room adopts a full-transparent non-traditional building built by glass and a metal frame so as to achieve the purposes of enjoying sunlight and being close to nature. The sunlight house is a building which is advocated by people pursuing nature and fashion at home and abroad. The sunshine room is designed and built according to the use requirements of places and personal preference in the victory industry widely researched in Shanghai areas in North China, and the indoor arrangement can be decorated according to the personal preference. Balcony or terrace sunny rooms, in whole dwelling rooms, visual connectivity is very important. It is necessary to consider the overall style of the building to be consistent with the overall tone of the building.

In the prior art, a power supply driving system of a sunlight room usually adopts an externally exposed form, and has no wiring and control system of a system, so that certain defects and potential safety hazards of a power supply mode exist.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an intelligent power supply system of a sunlight room.

In order to achieve the purpose, the invention provides the following technical scheme: an intelligent power supply system for a sunlight room, comprising:

a sunlight room main body;

the main control system is arranged in the sunlight room main body;

the power storage unit and the power utilization unit are connected with the master control system;

the solar power generation unit is laid outside the sunlight room main body;

the solar power generation unit is connected with the master control system, is connected with the power storage unit through the master control system to charge the power storage unit, and simultaneously supplies power to the master control system;

the power utilization unit is connected with the master control system, is connected with the power storage unit through the master control system to supply power to the power utilization unit, and is controlled by the master control system to execute actions of the power utilization unit;

the main control system comprises a main processor and a charging input module which is connected with the main processor and is used for power generation input, wherein the power generation input module is used for transferring and switching electric energy of the solar power generation unit and the power supply output module;

the power supply output module is connected with the main processor, is used for connecting the charging input module, transmitting electric energy to charge the electricity storage unit, and is connected with the electricity storage unit to output the electric energy to electric equipment;

the voltage monitoring unit is connected with the main processor and is used for detecting the voltage state information of the power storage unit and feeding the information back to the main processor;

the control module is connected with the main processor, is used for connecting electric equipment and controlling the action execution of the electric equipment, and is controlled by the main processor;

the power storage unit is connected with the master control system and is provided with a plurality of groups of storage battery packs with different output voltages, and the number of the storage battery packs with each output voltage is more than two;

the storage battery management module is connected with a plurality of groups of storage battery packs, independently detects and monitors the capacity state and the temperature state of each storage battery pack, transmits the state of the storage battery pack to the outside by visual signals and controls and executes preset actions;

the solar power generation unit comprises a plurality of solar photovoltaic panels for power generation and a power generation management module which is used for controlling the solar photovoltaic panels in series and parallel connection, is connected with the main processor and is controlled by the main processor; a plurality of groups of power generation transfer switches are arranged in the power generation management module, and each group of transfer switches are respectively connected with each group of solar photovoltaic panels;

the power utilization unit comprises temperature adjusting equipment for adjusting the space in the sunlight room body, sun shading equipment for shading sun and adjusting light, door and window equipment for controlling doors and windows, lighting equipment for lighting and power supply equipment for supplying power to other functional equipment;

a wireless transmitting unit for sending out a control signal; the wireless transmitting unit transmits an action signal of the electric equipment to the master control system.

Preferably, the master control system is provided with the main processor, and the main processor is connected with the power generation input module and is connected with a plurality of groups of power supply transfer switches arranged on the power generation input module; the main processor is also connected with the power generation management module arranged in the solar power generation unit.

Preferably, the main processing is connected with the power generation management module through the power generation input module, the plurality of solar photovoltaic panels generate electric energy after being irradiated by sunlight, and the electric energy is transmitted to the power generation input module through the power generation management module.

Preferably, before the charging management module transmits the electric energy to the power generation input module, the main processor controls the power generation management module to control the plurality of solar photovoltaic panels to be connected in series or in parallel or to be independently output;

the power management module combines a plurality of solar photovoltaic panels in a combination mode of mutually connecting in series, in parallel or independently outputting through a plurality of groups of independent and mutually connected change-over switches arranged inside to form a plurality of combined outputs, so that the voltage and the power of power generation are adjusted according to different power generation requirements;

the power management module is characterized in that multiple groups of independent and mutually connected change-over switches are arranged in the power management module, multiple combinations are formed by mutually connecting the multiple solar photovoltaic panels in series or in parallel or in an independent output mode, and the power generation electric energy generated by the multiple combinations is transmitted to the power generation input module in a single-path or multi-path mode.

Preferably, the power generation input module is controlled by the main processor to be connected with the power supply output unit; a plurality of groups of independent and mutually connected transfer switches for power supply output are arranged in the power supply output unit;

the main processor is connected with the transfer switch of the power supply output module through the transfer switch for controlling the power generation input module, and transmits the electric energy generated by the solar photovoltaic panel to the power supply output module.

Preferably, the main processor is connected with the electricity storage unit through a power supply output module and charges the electricity storage unit; the power supply output module is respectively connected with a plurality of storage battery packs arranged in the power storage unit through a plurality of groups of transfer switches for charging, and the storage battery packs are charged in an independent or multi-combination mode;

before the power supply output module charges a single or a plurality of storage battery packs, the power supply output module is controlled by the main processor to charge the storage battery packs needing to be charged;

the main processor is connected with the electricity storage unit through the voltage monitoring unit and is connected with a plurality of groups of storage battery packs arranged in the electricity storage unit, so that the voltage state of each group of storage battery packs is monitored, when the voltage of one or more groups of storage battery packs is monitored to be too low, the voltage monitoring unit feeds back low-voltage signals of the corresponding storage battery packs to the main processor, the main processor is connected with the transfer switch of the corresponding storage battery pack through controlling the power supply output module, and the charging electric energy is transmitted to the storage battery packs to charge the storage battery packs;

the power supply output module is used for controlling a power generation management module of the solar power generation unit before one or more storage battery packs are charged, controlling a plurality of solar photovoltaic panels to be combined in a serial connection, parallel connection or independent output mode according to the charging voltage and the number of the storage battery groups required by the storage battery to be charged, and transmitting the combined single-path or multi-path power generation electric energy to the power generation input module; and the main processor controls the corresponding transfer switch arranged in the power generation input module to be connected and conducted with a transfer switch which is used for charging and is connected with a charging storage battery pack in the power supply output module.

Preferably, the electric devices include a temperature adjusting device for adjusting the space in the sunlight room body, a sun shading device for shading sunlight and adjusting light, a door and window device for controlling a door and a window, an illuminating device for illuminating, and the like, which are required for realizing the functions of the sunlight room; the electric equipment is provided with different voltage levels according to the use function.

Preferably, the main processor supplies power to the electric equipment correspondingly according to different voltages of the electric equipment; the main processor is respectively connected with the electric equipment through a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack, and supplies power to the electric equipment;

before the main processor controls the power supply output module to output the electric energy of the storage battery pack to supply power to the electric equipment, the main processor also controls a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack to switch on the storage battery pack which accords with the voltage of the electric equipment according to the set voltage grade used by the electric equipment.

Preferably, the storage battery management module is arranged on the electricity storage unit; the storage battery management module monitors the discharge capacity of the storage battery pack; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement, so that a user can replace the corresponding storage battery pack conveniently;

the storage battery pack is a lithium battery pack, the lithium battery pack is formed by combining different voltages into an electricity storage unit, and the lithium battery pack is simultaneously provided with at least two lithium battery packs with the same voltage according to actual requirements; the lithium battery packs are mutually independent, and only when the power supply of the batteries is switched, the two lithium batteries with the same voltage are connected in parallel for power supply.

Preferably, a storage battery management module arranged in the electricity storage unit monitors the temperature of the storage battery pack; when the storage battery management module monitors that the temperature of the storage battery pack is higher than the use temperature, the storage battery management module feeds back an overhigh temperature signal of the corresponding storage battery pack in a visual signal mode and performs cutting off the electric energy input and output of the storage battery pack;

the transfer switch is used for the power generation management module, the power generation input unit and the power supply output unit and is an electromagnetic switch, a plurality of electromagnetic switches are arranged and are connected with one another or indirectly, and circuit connection of different functions is achieved by controlling conduction of different electromagnetic switches.

The invention has the technical effects and advantages that: compared with the prior art, the intelligent power supply system for the sunlight room is formed by the main control system, the power generation input unit, the power supply output unit, the voltage monitoring unit, the storage battery pack, the storage battery management module, the power generation management module, the solar photovoltaic panel and other structures, the intelligent power supply system for the sunlight room generates power through solar energy, stores electric energy through the storage battery, and simultaneously is provided with the monitoring unit to monitor each power generation process to form the intelligent power supply system for the sunlight room, so that the problems of a power supply mode and potential safety hazards of the sunlight room in the prior art are solved.

Drawings

FIG. 1 is a system block diagram of an intelligent power supply system for a sunlight room of the present invention;

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

An intelligent power supply system for a sunlight room, comprising:

a sunlight room main body;

the main control system is arranged in the sunlight room main body;

the power storage unit and the power utilization unit are connected with the master control system;

the solar power generation unit is laid outside the sunlight room main body;

the solar power generation unit is connected with the master control system, is connected with the power storage unit through the master control system to charge the power storage unit, and simultaneously supplies power to the master control system;

the power utilization unit is connected with the master control system, is connected with the power storage unit through the master control system to supply power to the power utilization unit, and is controlled by the master control system to perform actions of the power utilization unit;

the main control system comprises a main processor and a charging input module which is connected with the main processor and is used for power generation input, wherein the power generation input module is used for transferring and switching the electric energy of the solar power generation unit and the power supply output module;

the power supply output module is connected with the main processor, is used for connecting the charging input module, transmitting electric energy to charge the electricity storage unit and is connected with the electricity storage unit to output the electric energy to the electric equipment;

the voltage monitoring unit is connected with the main processor and is used for detecting the voltage state information of the power storage unit and feeding the information back to the main processor;

the control module is connected with the main processor, is used for connecting the electric equipment and controlling the electric equipment to act and execute, and is controlled by the main processor;

the storage unit is connected with the master control system and is provided with a plurality of groups of storage battery packs with different output voltages, and the number of the storage battery packs with each output voltage is more than two;

the storage battery management module is connected with a plurality of groups of storage battery packs, independently detects and monitors the capacity state and the temperature state of each storage battery pack, transmits the state of the storage battery packs outwards by visual signals and controls and executes preset actions;

the solar power generation unit comprises a plurality of solar photovoltaic panels for power generation and a power generation management module which is used for controlling the solar photovoltaic panels in series and parallel, is connected with the main processor and is controlled by the main processor; a plurality of groups of power generation transfer switches are arranged in the power generation management module, and each group of transfer switches are respectively connected with each group of solar photovoltaic panels;

the power utilization unit comprises a temperature adjusting device for adjusting the space in the sunlight room main body, a sun shading device for shading sun and adjusting light, a door and window device for controlling doors and windows, a lighting device for lighting and a power supply device for supplying power to other functional devices;

a wireless transmitting unit for sending out a control signal; the wireless transmitting unit transmits the action signal of the control electric equipment to the main control system.

The master control system is provided with a main processor, and the main processor is connected with the power generation input module and is connected with a plurality of groups of power supply transfer switches arranged on the power generation input module; the main processor is also connected with a power generation management module arranged in the solar power generation unit.

The main processing is connected with the power generation management module through the power generation input module, the plurality of solar photovoltaic panels generate electric energy after being irradiated by sunlight, and the electric energy is transmitted to the power generation input module through the power generation management module.

Before the charging management module transmits the electric energy to the power generation input module, the main processor controls the plurality of solar photovoltaic panels to be mutually connected in series or in parallel or to be independently output by controlling the power generation management module;

the power management module combines a plurality of solar photovoltaic panels in a combination mode of mutually connecting in series, in parallel or independently outputting through a plurality of groups of independent and mutually connected change-over switches arranged inside to form a plurality of combined outputs, so that the voltage and the power of power generation are adjusted according to different power generation requirements;

the power management module forms a plurality of combinations of the plurality of solar photovoltaic panels in a mode of mutually connecting in series or in parallel or independently outputting through a plurality of groups of independent and mutually connected change-over switches arranged inside, and transmits the generated electric energy generated by the plurality of combinations to the power generation input module in a single-path or multi-path mode.

The power generation input module is controlled by the main processor and is connected with the power supply output unit; a plurality of groups of independent and mutually connected transfer switches for power supply output are arranged in the power supply output unit;

the main processor is connected with the transfer switch of the power supply output module through the transfer switch for controlling the power generation input module, and transmits the electric energy generated by the solar photovoltaic panel to the power supply output module.

The main processing is connected with the electricity storage unit through the power supply output module and charges the electricity storage unit; the power supply output module is respectively connected with a plurality of storage battery packs arranged in the power storage unit through a plurality of groups of transfer switches for charging, and the single or a plurality of storage battery packs are charged in an independent or multi-combination mode;

before the power supply output module charges a single or a plurality of storage battery packs, the power supply output module is controlled by the main processor to charge the storage battery packs needing to be charged;

the main processor is connected with the electricity storage unit through the voltage monitoring unit and is connected with a plurality of groups of storage battery packs arranged in the electricity storage unit, so that the voltage state of each group of storage battery packs is monitored, when the voltage of one or more groups of storage battery packs is monitored to be too low, the voltage monitoring unit feeds back low-voltage signals of the corresponding storage battery packs to the main processor, the main processor is connected with the transfer switches of the corresponding storage battery packs through the control power supply output module, the charging electric energy is transmitted to the storage battery packs, and the storage battery packs are charged;

the power supply output module is used for controlling a power generation management module of the solar power generation unit before charging a single or a plurality of storage battery packs, controlling a plurality of solar photovoltaic panels to be combined in a serial connection, parallel connection or independent output mode according to the charging voltage and the number of the storage battery packs to be charged, and transmitting the combined single-path or multi-path power generation electric energy to the power generation input module; and the main processor controls the corresponding transfer switch arranged in the power generation input module to be connected and conducted with a transfer switch which is used for charging and is connected with the charging storage battery pack in the power supply output module.

The electric equipment comprises temperature adjusting equipment for adjusting the space in the sunlight room main body, shading equipment for shading sunlight and adjusting light, door and window equipment for controlling doors and windows, lighting equipment for lighting and the like, and the electric equipment is required for realizing the functions of the sunlight room; the electric equipment is provided with different voltage levels according to the use function.

The main processor correspondingly supplies power to the electric equipment according to different voltages of the electric equipment; the main processor is respectively connected with the electric equipment through a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack, and supplies power to the electric equipment;

before the main processor controls the power supply output module to output the electric energy of the storage battery pack to supply power to the electric equipment, the main processor also controls a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack to switch on the storage battery pack which accords with the voltage of the electric equipment according to the set voltage grade used by the electric equipment.

The electricity storage unit is provided with a storage battery management module; the storage battery management module monitors the discharge capacity of the storage battery pack; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement, so that a user can replace the corresponding storage battery pack conveniently;

the storage battery pack is a lithium battery pack, the lithium battery pack is formed by combining different voltages into an electricity storage unit, and the lithium battery pack is provided with at least two lithium battery packs with the same voltage according to actual requirements; the lithium battery packs are mutually independent, and only when the power supply of the batteries is switched, the two lithium batteries with the same voltage are connected in parallel for power supply.

A storage battery management module arranged on the electricity storage unit monitors the temperature of the storage battery pack; when the storage battery management module monitors that the temperature of the storage battery pack is higher than the use temperature, the storage battery management module feeds back an overhigh temperature signal of the corresponding storage battery pack in a visual signal mode and performs cutting off the electric energy input and output of the storage battery pack;

the transfer switch is used for the power generation management module, the power generation input unit and the power supply output unit and is an electromagnetic switch, a plurality of electromagnetic switches are arranged and are connected with one another or indirectly, and circuit connection of different functions is achieved by controlling conduction of different electromagnetic switches.

In summary, the following steps: compared with the prior art, the intelligent power supply system for the sunlight room is formed by the main control system, the power generation input unit, the power supply output unit, the voltage monitoring unit, the storage battery pack, the storage battery management module, the power generation management module, the solar photovoltaic panel and other structures, the intelligent power supply system for the sunlight room generates power through solar energy, stores electric energy through the storage battery, and simultaneously is provided with the monitoring unit to monitor each power generation process to form the intelligent power supply system for the sunlight room, so that the problems of a power supply mode and potential safety hazards of the sunlight room in the prior art are solved.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. An intelligent power supply system of a sunlight room, comprising:

a sunlight room main body;

the main control system is arranged in the sunlight room main body;

the power storage unit and the power utilization unit are connected with the master control system;

the solar power generation unit is laid outside the sunlight room main body;

the solar power generation unit is connected with the master control system, is connected with the power storage unit through the master control system to charge the power storage unit, and simultaneously supplies power to the master control system;

the power utilization unit is connected with the master control system, is connected with the power storage unit through the master control system to supply power to the power utilization unit, and is controlled by the master control system to execute actions of the power utilization unit;

the main control system comprises a main processor and a charging input module which is connected with the main processor and is used for power generation input, wherein the power generation input module is used for transferring and switching electric energy of the solar power generation unit and the power supply output module;

the power supply output module is connected with the main processor, is used for connecting the charging input module, transmitting electric energy to charge the electricity storage unit, and is connected with the electricity storage unit to output the electric energy to electric equipment;

the voltage monitoring unit is connected with the main processor and is used for detecting the voltage state information of the power storage unit and feeding the information back to the main processor;

the control module is connected with the main processor, is used for connecting electric equipment and controlling the action execution of the electric equipment, and is controlled by the main processor;

the power storage unit is connected with the master control system and is provided with a plurality of groups of storage battery packs with different output voltages, and the number of the storage battery packs with each output voltage is more than two;

the storage battery management module is connected with a plurality of groups of storage battery packs, independently detects and monitors the capacity state and the temperature state of each storage battery pack, transmits the state of the storage battery pack to the outside by visual signals and controls and executes preset actions;

the solar power generation unit comprises a plurality of solar photovoltaic panels for power generation and a power generation management module which is used for controlling the solar photovoltaic panels in series and parallel connection, is connected with the main processor and is controlled by the main processor; a plurality of groups of power generation transfer switches are arranged in the power generation management module, and each group of transfer switches are respectively connected with each group of solar photovoltaic panels;

the power utilization unit comprises temperature adjusting equipment for adjusting the space in the sunlight room body, sun shading equipment for shading sun and adjusting light, door and window equipment for controlling doors and windows, lighting equipment for lighting and power supply equipment for supplying power to other functional equipment;

a wireless transmitting unit for sending out a control signal; the wireless transmitting unit transmits an action signal of the electric equipment to the master control system.

2. The intelligent power supply system of the sunlight room of claim 1, wherein: the master control system is provided with the main processor, and the main processor is connected with the power generation input module and is connected with a plurality of groups of power supply transfer switches arranged on the power generation input module; the main processor is also connected with the power generation management module arranged in the solar power generation unit.

3. The intelligent power supply system for the sunlight room as claimed in claim 2, wherein: the main processing is connected with the power generation management module through the power generation input module, the plurality of solar photovoltaic panels generate electric energy after being irradiated by sunlight, and the electric energy is transmitted to the power generation input module through the power generation management module.

4. The intelligent power supply system of the sunlight room of claim 1, wherein: before the charging management module transmits the electric energy to the power generation input module, the main processor controls the power generation management module to control the plurality of solar photovoltaic panels to be connected in series or in parallel or to be independently output;

the power management module combines a plurality of solar photovoltaic panels in a combination mode of mutually connecting in series, in parallel or independently outputting through a plurality of groups of independent and mutually connected change-over switches arranged inside to form a plurality of combined outputs, so that the voltage and the power of power generation are adjusted according to different power generation requirements;

the power management module is characterized in that multiple groups of independent and mutually connected change-over switches are arranged in the power management module, multiple combinations are formed by mutually connecting the multiple solar photovoltaic panels in series or in parallel or in an independent output mode, and the power generation electric energy generated by the multiple combinations is transmitted to the power generation input module in a single-path or multi-path mode.

5. The intelligent power supply system of the sunlight room of claim 1, wherein: the power generation input module is controlled by the main processor to be connected with the power supply output unit; a plurality of groups of independent and mutually connected transfer switches for power supply output are arranged in the power supply output unit;

the main processor is connected with the transfer switch of the power supply output module through the transfer switch for controlling the power generation input module, and transmits the electric energy generated by the solar photovoltaic panel to the power supply output module.

6. The intelligent power supply system of the sunlight room of claim 1, wherein: the main processing is connected with the electricity storage unit through a power supply output module and charges the electricity storage unit; the power supply output module is respectively connected with a plurality of storage battery packs arranged in the power storage unit through a plurality of groups of transfer switches for charging, and the storage battery packs are charged in an independent or multi-combination mode;

before the power supply output module charges a single or a plurality of storage battery packs, the power supply output module is controlled by the main processor to charge the storage battery packs needing to be charged;

the main processor is connected with the electricity storage unit through the voltage monitoring unit and is connected with a plurality of groups of storage battery packs arranged in the electricity storage unit, so that the voltage state of each group of storage battery packs is monitored, when the voltage of one or more groups of storage battery packs is monitored to be too low, the voltage monitoring unit feeds back low-voltage signals of the corresponding storage battery packs to the main processor, the main processor is connected with the transfer switch of the corresponding storage battery pack through controlling the power supply output module, and the charging electric energy is transmitted to the storage battery packs to charge the storage battery packs;

the power supply output module is used for controlling a power generation management module of the solar power generation unit before one or more storage battery packs are charged, controlling a plurality of solar photovoltaic panels to be combined in a serial connection, parallel connection or independent output mode according to the charging voltage and the number of the storage battery groups required by the storage battery to be charged, and transmitting the combined single-path or multi-path power generation electric energy to the power generation input module; and the main processor controls the corresponding transfer switch arranged in the power generation input module to be connected and conducted with a transfer switch which is used for charging and is connected with a charging storage battery pack in the power supply output module.

7. The intelligent power supply system of the sunlight room of claim 1, wherein: the electric equipment comprises temperature adjusting equipment for adjusting the space in the sunlight room main body, sun shading equipment for shading sun and adjusting light, door and window equipment for controlling doors and windows, lighting equipment for lighting and the like, and the electric equipment is required for realizing the functions of the sunlight room; the electric equipment is provided with different voltage levels according to the use function.

8. The intelligent power supply system of the sunlight room of claim 1, wherein: the main processor correspondingly supplies power to the electric equipment according to different voltages of the electric equipment; the main processor is respectively connected with the electric equipment through a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack, and supplies power to the electric equipment;

before the main processor controls the power supply output module to output the electric energy of the storage battery pack to supply power to the electric equipment, the main processor also controls a transfer switch which is arranged in the power supply output module and used for outputting the electric energy of the storage battery pack to switch on the storage battery pack which accords with the voltage of the electric equipment according to the set voltage grade used by the electric equipment.

9. The intelligent power supply system of the sunlight room of claim 1, wherein: the storage battery management module is arranged on the electricity storage unit; the storage battery management module monitors the discharge capacity of the storage battery pack; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement; when the storage battery management module monitors that the discharge capacity is lower than a set value, the use state of the storage battery is fed back in a visual signal mode to remind that the electric energy capacity of the storage battery pack is lower than the use requirement, so that a user can replace the corresponding storage battery pack conveniently;

the storage battery pack is a lithium battery pack, the lithium battery pack is formed by combining different voltages into an electricity storage unit, and the lithium battery pack is simultaneously provided with at least two lithium battery packs with the same voltage according to actual requirements; the lithium battery packs are mutually independent, and only when the power supply of the batteries is switched, the two lithium batteries with the same voltage are connected in parallel for power supply.

10. The intelligent power supply system of the sunlight room of claim 1, wherein: a storage battery management module arranged on the electricity storage unit monitors the temperature of the storage battery pack; when the storage battery management module monitors that the temperature of the storage battery pack is higher than the use temperature, the storage battery management module feeds back an overhigh temperature signal of the corresponding storage battery pack in a visual signal mode and performs cutting off the electric energy input and output of the storage battery pack;

the transfer switch is used for the power generation management module, the power generation input unit and the power supply output unit and is an electromagnetic switch, a plurality of electromagnetic switches are arranged and are connected with one another or indirectly, and circuit connection of different functions is achieved by controlling conduction of different electromagnetic switches.

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