CN220152836U - Multi-scene solar stall vehicle system - Google Patents

Abstract

The present disclosure relates to a multi-scenario solar energy stall vehicle system, comprising: a photoelectric conversion subsystem and a photothermal conversion subsystem; the photoelectric conversion subsystem is used for converting light energy into electric energy; the electric energy is used for supplying power for the stall vehicle system; the photo-thermal conversion subsystem is used for converting light energy into heat energy; the heat energy is used for heating the stall vehicle system. The photoelectric conversion subsystem and the photo-thermal conversion subsystem are arranged in the stall vehicle system, the photoelectric conversion subsystem can fully utilize solar energy to convert into electric energy, and the photo-thermal conversion subsystem can utilize the solar energy to convert into heat energy, so that petroleum energy sources in related technologies can be replaced, pollution is reduced, and the stall vehicle system is beneficial to realizing green and environment protection.

Description

Multi-scene solar stall vehicle system

Technical Field

The disclosure relates to the technical field of photovoltaics, in particular to a multi-scene solar stall vehicle system.

Background

Stall vehicles are very common in cities, most of stall vehicles process food by adopting electricity or liquefied petroleum gas, the electricity is generally generated by burning fossil energy such as coal, the environment is greatly polluted, the liquefied petroleum gas is inflammable and explosive, and once the stall vehicles are used irregularly, the stall vehicles can have great danger.

Disclosure of Invention

In order to overcome the problems in the related art, the present disclosure provides a multi-scenario solar energy stall system to solve the above-mentioned problems.

According to a first aspect of embodiments of the present disclosure, there is provided a multi-scenario solar energy stall system, comprising:

a photoelectric conversion subsystem and a photothermal conversion subsystem;

the photoelectric conversion subsystem is used for converting light energy into electric energy; the electric energy is used for supplying power for the stall vehicle system;

the photo-thermal conversion subsystem is used for converting light energy into heat energy; the heat energy is used for heating the stall vehicle system.

In one embodiment, the photoelectric conversion subsystem comprises a solar photovoltaic panel, an energy storage device, an inverter and a plurality of electric devices;

the solar photovoltaic panel is used for converting light energy into electric energy;

the energy storage device is used for storing the electric energy converted by the solar photovoltaic panel;

the inverter is connected with the energy storage device and is used for inverting direct current in the energy storage device into alternating current;

the plurality of electric equipment is used for using the alternating current provided by the inverter.

In one embodiment, the solar energy storage device further comprises a charge-discharge controller, wherein the charge-discharge controller is respectively connected with the solar photovoltaic panel and the energy storage device;

the photo-thermal conversion subsystem at least comprises a solar heat collector, a heat preservation water tank and a radiator;

the solar heat collector is used for converting light energy into heat energy;

the heat preservation water tank is connected with the solar heat collector;

the radiator is connected with the heat preservation water tank and used for radiating heat.

In one embodiment, the system further comprises a first conduit and a second conduit;

the first pipeline is connected with the water outlet of the heat preservation water tank and the water inlet of the radiator;

the second pipeline is connected with a water inlet of the heat preservation water tank and a water outlet of the radiator;

a water pump and a first valve are arranged on the first pipeline;

a second valve is arranged on the second pipeline;

when the first valve and the second valve are opened, and the water pump works, water in the heat preservation water tank enters the radiator and returns to the heat preservation water tank after passing through the radiator, so that water circulation is formed.

In one embodiment, the food processing system further comprises a cooked food heat preservation cabinet, a third pipeline and a fourth pipeline;

the third pipeline is connected with a water inlet of the heat preservation water tank and a water outlet of the cooked food heat preservation cabinet;

the third pipeline is connected with the water inlet of the cooked food heat preservation cabinet and the first pipeline;

the intersection point of the third pipeline and the first pipeline is positioned between the water pump on the first pipeline and the first valve;

a third valve is arranged on the third pipeline;

a fourth valve is arranged on the fourth pipeline;

when the first valve and the second valve are closed, the third valve and the fourth valve are opened, and when the water pump works, water in the heat preservation water tank enters the cooked food heat preservation cabinet and returns to the heat preservation water tank after passing through the cooked food heat preservation cabinet, so that water circulation is formed.

In one embodiment, the device further comprises a thermometer; the thermometer is used for detecting the water temperature of the cooked food heat preservation cabinet.

The technical scheme provided by the embodiment of the disclosure can comprise the following beneficial effects:

according to the technical scheme, the photoelectric conversion subsystem and the photo-thermal conversion subsystem are arranged in the stall vehicle system, the photoelectric conversion subsystem can fully utilize solar energy to convert into electric energy, and the photo-thermal conversion subsystem can utilize the solar energy to convert into heat energy, so that petroleum energy sources in related technologies can be replaced, pollution is reduced, and environmental protection is facilitated.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure.

FIG. 1 is a schematic diagram of a multi-scenario solar energy kiosk system according to one exemplary embodiment;

fig. 2 is a schematic diagram illustrating a multi-scenario solar energy kiosk system according to an example embodiment.

Description of the reference numerals

The intelligent solar energy power generation system comprises a 01-photoelectric conversion subsystem, a 02-photothermal conversion subsystem 02, 0-electric equipment, a 1-solar photovoltaic panel, a 2-charge and discharge controller, a 3-energy storage device, a 4-inverter, a 5-solar heat collector, a 6-heat preservation water tank, a 7-water pump, an 8-fourth valve, a 9-third valve, a 10-first quick-release connector, a 11-second quick-release connector, a 12-cooked food heat preservation cabinet, a 13-thermometer, a 14-first valve, a 15-second valve, a 16-third quick-release connector, a 17-fourth quick-release connector, a 18-radiator, a 21-first pipeline, a 22-second pipeline, a 23-third pipeline and a 24-fourth pipeline.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated.

A multi-scenario solar energy stall system comprising: a photoelectric conversion subsystem 01 and a photothermal conversion subsystem 02.

The photoelectric conversion subsystem 01 is used for converting light energy into electric energy; the electric energy is used for supplying power for the stall vehicle system;

the photo-thermal conversion subsystem 02 is used for converting light energy into heat energy; the heat energy is used for heating the stall vehicle system.

According to the technical scheme, the photoelectric conversion subsystem and the photo-thermal conversion subsystem are arranged, the photoelectric conversion subsystem can fully utilize solar energy to convert into electric energy, and the photo-thermal conversion subsystem can utilize the solar energy to convert into heat energy, so that petroleum energy sources in related technologies can be replaced, pollution is reduced, and environmental protection is facilitated.

In one embodiment, the photoelectric conversion subsystem 01 includes a solar photovoltaic panel 1, an energy storage device 3, an inverter 4, and a plurality of electrical consumers 0.

The solar photovoltaic panel 1 is used for converting light energy into electric energy.

The energy storage device 3 is used for storing the electric energy converted by the solar photovoltaic panel 1.

And an inverter 4, wherein the inverter 4 is connected with the energy storage device 3 and is used for inverting the direct current in the energy storage device 3 into alternating current.

The plurality of electric devices 0 are configured to use the ac power provided by the inverter 4.

In this embodiment, the solar photovoltaic panel 1 converts solar energy into electric energy, the electric energy is stored in the energy storage device 3 through the charge-discharge controller 2, the inverter 4 converts direct current of the energy storage device 3 into alternating current, and the alternating current is provided for the electric equipment 0, so that the electric equipment works. Wherein, above-mentioned consumer includes: cooking equipment, lighting equipment, refrigeration equipment, air conditioning equipment and power equipment.

In one embodiment, the solar energy storage device further comprises a charge-discharge controller 2, and the charge-discharge controller 2 is connected with the solar photovoltaic panel 1 and the energy storage device 3 respectively.

The charge-discharge controller 2 may control the solar photovoltaic panel 1 to charge the energy storage device 3. The energy storage device 3 can also be controlled to discharge a plurality of electric devices.

The photo-thermal conversion subsystem 02 at least comprises a solar heat collector 5, a heat preservation water tank 6 and a radiator 18;

the solar collector 5 is used for converting light energy into heat energy.

The heat preservation water tank 6 is connected with the solar heat collector 5, and water in the heat preservation water tank 6 can be heated under the action of the solar heat collector 5.

The radiator 18 is connected with the heat preservation water tank 6 and used for radiating heat.

In this embodiment, a connecting pipeline may be disposed between the radiator 18 and the heat-preserving water tank 6, so as to implement water circulation, and hot water in the heat-preserving water tank 6 may pass through the radiator 18, so that the radiator 18 may play a role in heating. The radiator can be arranged in the stall vehicle, so that the solar energy is utilized to heat.

In one embodiment, the first and second pipes 21 and 22 are also included.

The first pipe 21 connects the water outlet of the heat preservation water tank 6 and the water inlet of the radiator 18.

The second pipe 22 connects the water inlet of the heat preservation water tank 6 and the water outlet of the radiator 18.

A water pump 7 and a first valve 14 are arranged on said first conduit 21.

A second valve 15 is arranged on said second conduit 22.

When the first valve 14 and the second valve 15 are opened, the water in the heat preservation water tank 6 enters the radiator 18 when the water pump 7 works, and returns to the heat preservation water tank 6 after passing through the radiator 18, so that water circulation is formed.

In one embodiment, the food warmer 12, third duct 23, and fourth duct 24 are also included.

The third pipeline 23 is connected with the water inlet of the heat preservation water tank 6 and the water outlet of the cooked food heat preservation cabinet 12.

The third pipe 23 connects the water inlet of the cooked food heat-preserving cabinet 12 with the first pipe 21.

The intersection point of the third pipeline 23 and the first pipeline 21 is positioned between the water pump 7 on the first pipeline 21 and the first valve 14;

a third valve 9 is provided on the third conduit 23.

A fourth valve 8 is arranged on said fourth conduit 24.

When the first valve 14 and the second valve 15 are closed, the third valve 9 and the fourth valve 8 are opened, and the water pump 7 works, water in the heat preservation water tank 6 enters the cooked food heat preservation cabinet 12, passes through the cooked food heat preservation cabinet 12 and returns to the heat preservation water tank 6 to form water circulation.

In one embodiment, the thermometer 13 is further included; the thermometer 13 is used for detecting the water temperature of the cooked food heat preservation cabinet 12.

In one embodiment, the method further comprises: a first quick disconnect 10 and a second quick disconnect 11;

a first quick release connector 10 connected to the water inlet of the cooked food heat preservation cabinet 12 and one end of the fourth pipe 24;

and the second quick-release connector 11 is connected with the water outlet of the cooked food heat preservation cabinet 12 and one end of the third pipeline.

In one embodiment, the method further comprises: a third quick release connector 16 and a fourth quick release connector 17;

the third quick release connector 16 connects the water outlet of the radiator 18 and one end of the second pipe 22.

The third quick release connector 17 connects the water inlet of the radiator 18 and one end of the first pipe 21.

The use of the cooked food heat preservation cabinet when the temperature is low in winter is described as follows, and the cooked food heat preservation cabinet is needed to keep the temperature of the fast food dishes due to the fact that the outdoor temperature is low in winter. The heat preservation box is connected with a pipeline through a first quick-release connector 10 and a second quick-release connector 11, the water pump 7 is opened, the fourth valve 8 and the fourth valve 9 are opened, the heat preservation water tank 6 absorbs solar radiant heat through the solar heat collector 5, the water temperature in the heat preservation water tank 6 is increased, water of the cooked food heat preservation cabinet 12 with lower temperature is continuously subjected to heat exchange with water in the heat preservation water tank 6 under the power of the water pump 7, so that the temperature of the water temperature in the cooked food heat preservation cabinet 12 is increased, the thermometer 13 is used for detecting the water temperature of the cooked food heat preservation cabinet 12, when the water temperature exceeds a preset first threshold value, the operation of the water pump 7 can be stopped, energy is saved, and when the water temperature is lower than the preset first threshold value, the water pump 7 is started, and the temperature of the cooked food heat preservation cabinet is maintained in a certain range.

The radiator is used when the winter temperature is low as described below, and the system further comprises a radiator 18 in order to provide a comfortable working environment for the practitioner. When the solar heat-preserving heat radiator is used, the fourth valve 8 and the fourth valve 9 are closed, the water pump 7 is opened, the first valve 14 and the second valve 15 are opened, the heat-preserving water tank 6 absorbs radiant heat of the sun through the solar heat collector 5, the water temperature in the heat-preserving water tank 6 is increased, the water temperature in the radiator 18 is increased under the power of the water pump 7, and the radiator 18 radiates heat through convection and radiation.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure. This application is intended to cover any adaptations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It is to be understood that the present disclosure is not limited to the precise arrangements and instrumentalities shown in the drawings, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (2)

1. A multi-scenario solar energy stall system, comprising:

a photoelectric conversion subsystem (01) and a photothermal conversion subsystem (02);

the photoelectric conversion subsystem (01) is used for converting light energy into electric energy; the electric energy is used for supplying power for the stall vehicle system;

the photo-thermal conversion subsystem (02) is used for converting light energy into heat energy; the heat energy is used for heating a stall vehicle system;

the photoelectric conversion subsystem (01) comprises a solar photovoltaic panel (1), an energy storage device (3), an inverter (4) and a plurality of electric equipment (0);

the solar photovoltaic panel (1) is used for converting light energy into electric energy;

the energy storage device (3) is used for storing the electric energy converted by the solar photovoltaic panel (1);

the inverter (4) is connected with the energy storage device (3) and is used for inverting direct current in the energy storage device (3) into alternating current;

the plurality of electric consumers (0) are used for using the alternating current provided by the inverter (4);

the solar energy photovoltaic system further comprises a charge and discharge controller (2), wherein the charge and discharge controller (2) is respectively connected with the solar photovoltaic panel (1) and the energy storage device (3);

the photo-thermal conversion subsystem (02) at least comprises a solar heat collector (5), a heat preservation water tank (6) and a radiator (18);

the solar collector (5) is used for converting light energy into heat energy;

the heat preservation water tank (6) is connected with the solar heat collector (5);

the radiator (18) is connected with the heat preservation water tank (6) and is used for radiating heat;

also comprises a first pipeline (21) and a second pipeline (22);

the first pipeline (21) is connected with a water outlet of the heat preservation water tank (6) and a water inlet of the radiator (18);

the second pipeline (22) is connected with a water inlet of the heat preservation water tank (6) and a water outlet of the radiator (18);

a water pump (7) and a first valve (14) are arranged on the first pipeline (21);

a second valve (15) is arranged on the second pipeline (22);

when the first valve (14) and the second valve (15) are opened, and the water pump (7) works, water in the heat preservation water tank (6) enters the radiator (18), passes through the radiator (18) and then returns to the heat preservation water tank (6) to form water circulation;

the food heat preservation cabinet also comprises a cooked food heat preservation cabinet (12), a third pipeline and a fourth pipeline;

the third pipeline is connected with a water inlet of the heat preservation water tank (6) and a water outlet of the cooked food heat preservation cabinet (12);

the third pipeline is connected with a water inlet of the cooked food heat preservation cabinet (12) and the first pipeline;

the intersection point of the third pipeline and the first pipeline is positioned between a water pump (7) on the first pipeline and the first valve (14);

a third valve (9) is arranged on the third pipeline (23);

a fourth valve (8) is arranged on the fourth pipeline (24);

when the first valve (14) and the second valve (15) are closed, the third valve (9) and the fourth valve (8) are opened, and the water pump (7) works, water in the heat preservation water tank (6) enters into the cooked food heat preservation cabinet (12) and returns to the heat preservation water tank (6) after passing through the cooked food heat preservation cabinet (12) to form water circulation.

2. The multi-scenario solar energy stall system of claim 1, further comprising a thermometer (13);

the thermometer (13) is used for detecting the water temperature of the cooked food heat preservation cabinet (12).