CN217063605U - Wind, light, fire and heat energy storage multi-energy complementary system - Google Patents

Abstract

The utility model discloses a wind, light, fire and heat energy storage multi-energy complementary system, which comprises a power generation assembly, wherein the power generation assembly comprises a thermal power station, a photo-thermal power station, a wind power station, a photovoltaic controller and a wind power controller; the complementary mechanism comprises a steam energy accumulator, a warning lamp, a steam generator, an electric cabinet, a touch display screen, a wind speed sensor and a light intensity sensor; and a photo-thermal power station is arranged on one side of the thermal power station. The utility model discloses a solar energy and wind power generation are carried out respectively to light and heat power station and wind power station, then turn into steam heat energy through the electric energy that steam energy storage ware produced light and heat power station and wind power station, then generate electricity for steam generator provides steam through the steam energy storage ware to it is complementary to make to generate electricity between thermal power station, light and heat power station and the wind power station, and then has guaranteed the stability of electric energy output, has reduced the influence of external environment factor, has improved application scope.

Description

Wind, light, fire and heat energy storage multi-energy complementary system

The technical field is as follows:

the utility model relates to a power generation technical field specifically is a wind-solar-fire-heat energy storage multi-energy complementary system.

Background art:

the power generation is that a power generation power device is utilized to convert water energy, thermal energy of fossil fuel, nuclear energy, solar energy, wind energy, geothermal energy, ocean energy and the like into electric energy, the power generation is multipurpose fossil fuel at the end of 20 century, but the fossil fuel is few in resource and is gradually exhausted, and more renewable energy sources are used for generating power by human beings;

when the traditional wind power generation or solar power generation is used, the influence of external factors is easily caused, the randomness is high, and therefore continuous and stable electric energy output is difficult to provide, the application range of the wind power generation and the solar power generation is further reduced, the utilization rate of resources is influenced, and therefore the wind, light, fire, heat and storage multi-energy complementary system is provided.

The utility model has the following contents:

an object of the utility model is to provide a hot complementary system that stores up of scene fire to solve the problem that proposes in the above-mentioned background art.

The utility model discloses implement by following technical scheme: a wind, light, fire and heat energy storage multi-energy complementary system comprises

The power generation assembly comprises a thermal power station, a photo-thermal power station, a wind power station, a photovoltaic controller and a wind power controller;

the complementary mechanism comprises a steam energy accumulator, a warning lamp, a steam generator, an electric cabinet, a touch display screen, a wind speed sensor and a light intensity sensor;

one side of thermal power plant is equipped with the light and heat power station, the opposite side of thermal power plant is equipped with wind power station, steam accumulator is installed to inside one side of thermal power plant, steam generator is installed to the inside opposite side of thermal power plant, photovoltaic controller is installed to one side of light and heat power station, wind power controller is installed to one side of wind power station, photovoltaic controller and wind power controller's electrical output passes through wire electric connection in steam accumulator's electrical input end, the electric cabinet is installed to inside one side of thermal power plant.

As a further preferred aspect of the present invention: a storage groove is formed in the middle of the front surface of the electric cabinet, and a touch display screen is mounted on the inner side wall of the storage groove; and displaying the result calculated by the PLC through the touch display screen.

As a further preferred aspect of the present invention: a PLC controller is installed at the top of the inner side wall of the electric cabinet, and relays are evenly installed at the bottom of the inner side wall of the electric cabinet; and the opening and closing of the relay are controlled by the PLC.

As further preferable in the present technical solution: a support column is arranged on one side of the thermal power station, and a detection box is fixedly connected to the top of the support column; the bottom of the detection box is provided with supporting force through the supporting columns.

As a further preferred aspect of the present invention: the middle part of the upper surface of the detection box is provided with an air speed sensor, and the middle part of one side of the detection box is provided with a light intensity sensor; and detecting external wind speed data through a wind speed sensor.

As a further preferred aspect of the present invention: an air outlet of the steam energy accumulator is communicated with an air supply pipe, and one end of the air supply pipe is communicated with an air inlet of the steam generator; the steam is guided out to the steam generator through the air supply pipe, and then the steam generator is used for steam power generation.

As a further preferred aspect of the present invention: the middle part of the outer side wall of the air supply pipe is communicated with a steam electromagnetic valve, and the middle part of the upper surface of the electric cabinet is provided with a warning lamp; and an alarm is given through the warning lamp to remind a worker to check.

As a further preferred aspect of the present invention: the signal output ends of the touch display screen, the wind speed sensor and the illuminance sensor are electrically connected to the signal input end of the PLC through wires, the signal output end of the PLC is electrically connected to the signal input end of the touch display screen through wires, the electrical output end of the PLC is electrically connected to the electrical input end of the relay through wires, and the electrical output end of the relay is electrically connected to the electrical input ends of the steam electromagnetic valve and the warning lamp through wires; and receiving data of the touch display screen, the wind speed sensor and the illuminance sensor through the PLC.

The utility model has the advantages that:

1. the utility model discloses a solar energy and wind power generation are carried out respectively to light and heat power station and wind power station, then turn into steam heat energy through the electric energy that steam energy storage ware produced light and heat power station and wind power station, then generate electricity for steam generator provides steam through the steam energy storage ware to it is complementary to make to generate electricity between thermal power station, light and heat power station and the wind power station, and then has guaranteed the stability of electric energy output, has reduced the influence of external environment factor, has improved application scope.

2. The utility model discloses a wind speed sensor and illuminance sensor carry out the collection work to wind speed and illuminance data in the external environment respectively, then receive wind speed sensor and illuminance sensor's data through the PLC controller to calculate data, thereby predict the generated energy of light and heat power station and wind power station, and then make the staff can judge the generated energy of thermal power station according to data, improved the utilization ratio of resource, further ensured the stability of electric energy output.

Description of the drawings:

in order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic diagram of the side-axis structure of the detection box of the present invention;

FIG. 3 is a schematic view of a sectional structure of the electric cabinet of the present invention;

fig. 4 is a schematic side view of the present invention.

In the figure: 1. a power generation assembly; 2. a complementary mechanism; 101. a thermal power station; 102. a photo-thermal power station; 103. a wind power plant; 104. a photovoltaic controller; 105. a wind power controller; 201. a steam accumulator; 202. a warning light; 203. a steam generator; 204. an electric cabinet; 205. a touch display screen; 206. a wind speed sensor; 207. a light intensity sensor; 41. a support pillar; 42. a gas supply pipe; 43. a steam solenoid valve; 44. a storage groove; 45. a PLC controller; 46. a relay; 47. and (6) a detection box.

The specific implementation mode is as follows:

the technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a wind, light, fire and heat energy storage multi-energy complementary system comprises

The power generation assembly 1 comprises a thermal power station 101, a photo-thermal power station 102, a wind power station 103, a photovoltaic controller 104 and a wind power controller 105;

the complementary mechanism 2 comprises a steam energy storage 201, a warning light 202, a steam generator 203, an electric cabinet 204, a touch display screen 205, a wind speed sensor 206 and a light intensity sensor 207;

thermal power plant 101's one side is equipped with light and heat power station 102, thermal power plant 101's opposite side is equipped with wind power station 103, steam accumulator 201 is installed to thermal power plant 101's inside one side, steam generator 203 is installed to thermal power plant 101's inside opposite side, photovoltaic controller 104 is installed to light and heat power station 102's one side, wind power station 103's one side-mounting has wind electric controller 105, photovoltaic controller 104 and wind electric controller 105's electrical output passes through wire electric connection in steam accumulator 201's electrical input end, electric cabinet 204 is installed to thermal power plant 101's inside one side.

In this embodiment, specifically: a storage tank 44 is arranged in the middle of the front surface of the electric cabinet 204, and a touch display screen 205 is arranged on the inner side wall of the storage tank 44; and displaying the result calculated by the PLC 45 through the touch display screen 205 so that the working personnel can judge the power generation amount of the thermal power station according to the data.

In this embodiment, specifically: the top of the inner side wall of the electric cabinet 204 is provided with a PLC 45, and the bottom of the inner side wall of the electric cabinet 204 is uniformly provided with relays 46; the opening and closing of the relay 46 is controlled by the PLC controller 45.

In this embodiment, specifically: a support column 41 is arranged on one side of the thermal power station 101, and a detection box 47 is fixedly connected to the top of the support column 41; the bottom of the detection box 47 is provided with a supporting force by the supporting column 41.

In this embodiment, specifically: the middle part of the upper surface of the detection box 47 is provided with an air speed sensor 206, and the middle part of one side of the detection box 47 is provided with an illumination sensor 207; the wind speed sensor 206 detects wind speed data from the outside, and the illuminance sensor 207 detects illuminance data from the outside.

In this embodiment, specifically: an air outlet of the steam energy storage 201 is communicated with an air supply pipe 42, and one end of the air supply pipe 42 is communicated with an air inlet of the steam generator 203; the steam is guided into the steam generator 203 through the air supply pipe 42, and then the steam generator 203 performs a steam power generation operation.

In this embodiment, specifically: the middle part of the outer side wall of the air supply pipe 42 is communicated with a steam electromagnetic valve 43, and the middle part of the upper surface of the electric cabinet 204 is provided with a warning lamp 202; an alarm is given through the warning light 202 to remind the staff to check.

In this embodiment, specifically: the signal output ends of the touch display screen 205, the wind speed sensor 206 and the illuminance sensor 207 are electrically connected to the signal input end of the PLC controller 45 through wires, the signal output end of the PLC controller 45 is electrically connected to the signal input end of the touch display screen 205 through wires, the electrical output end of the PLC controller 45 is electrically connected to the electrical input end of the relay 46 through wires, and the electrical output end of the relay 46 is electrically connected to the electrical input ends of the steam solenoid valve 43 and the warning light 202 through wires; the data of the touch display screen 205, the wind speed sensor 206 and the light intensity sensor 207 are received by the PLC 45, and the opening and closing of the steam solenoid valve 43 and the warning light 202 are controlled by the relay 46.

Working principle or structural principle: when the device is used, solar energy is converted into electric energy through the photo-thermal power station 102, then wind energy is converted into electric energy through the wind power station 103, then the electric energy generated by the photo-thermal power station 102 and the wind power station 103 is respectively transmitted to the steam energy storage 201 through the photovoltaic controller 104 and the wind power controller 105, then the electric energy is converted into steam heat energy through the steam energy storage 201 to be stored, then steam is led out into the steam generator 203 through the air supply pipe 42, then steam power generation work is carried out through the steam generator 203, so that power generation complementation can be carried out among the thermal power station 101, the photo-thermal power station 102 and the wind power station 103, the influence of external environment influence is reduced, the application range of wind power generation and solar power generation is enlarged, then external wind speed data is detected through the wind speed sensor 206, and external light intensity data is detected through the light intensity sensor 207, then the PLC 45 receives data of the wind speed sensor 206 and the light intensity sensor 207, the PLC 45 calculates the data, the touch display screen 205 displays the calculation result of the PLC 45 so that a worker can judge the power generation amount of the thermal power station according to the data, resources consumed by the thermal power station are saved, when the data detected by the wind speed sensor 206 and the light intensity sensor 207 are lower than a threshold value, the PLC 45 and the relay 46 start the warning lamp 202 to work, the working warning lamp 202 gives an alarm to remind the worker to check, when the opening and closing of the air supply pipe 42 need to be controlled, a control instruction is transmitted to the PLC 45 through the touch display screen 205, then the relay 46 is started to work according to the data through the PLC 45, the working relay 46 controls the opening and closing of the steam electromagnetic valve 43, thereby opening and closing of control air supply pipe 42, the utility model discloses not only make the staff can judge the generated energy of thermal power station according to data, improved the utilization ratio of resource, guaranteed the stability of electric energy output, can generate electricity complementally moreover, reduced external environment factor's influence, improved application scope.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A wind, light, fire and heat energy storage multi-energy complementary system is characterized by comprising

The power generation assembly (1) comprises a thermal power station (101), a photo-thermal power station (102), a wind power station (103), a photovoltaic controller (104) and a wind power controller (105);

the device comprises a complementary mechanism (2), wherein the complementary mechanism (2) comprises a steam energy storage device (201), a warning lamp (202), a steam generator (203), an electric cabinet (204), a touch display screen (205), a wind speed sensor (206) and a light intensity sensor (207);

one side of thermal power station (101) is equipped with light and heat power station (102), the opposite side of thermal power station (101) is equipped with wind power station (103), steam energy storage ware (201) are installed to inside one side of thermal power station (101), steam generator (203) are installed to the inside opposite side of thermal power station (101), photovoltaic controller (104) are installed to one side of light and heat power station (102), wind electric controller (105) are installed to one side of wind power station (103), the electric output of photovoltaic controller (104) and wind electric controller (105) passes through wire electric connection in the electric input of steam energy storage ware (201), electric cabinet (204) are installed to inside one side of thermal power station (101).

2. The wind, light, fire, heat and energy storage multi-energy complementary system of claim 1, wherein: the middle part of the front surface of the electric cabinet (204) is provided with a storage groove (44), and a touch display screen (205) is installed on the inner side wall of the storage groove (44).

3. The wind, light, fire, heat and energy storage multi-energy complementary system of claim 1, wherein: the PLC controller (45) is installed at the top of the inner side wall of the electric cabinet (204), and the relays (46) are evenly installed at the bottom of the inner side wall of the electric cabinet (204).

4. The wind, light, fire, heat and energy storage multi-energy complementary system of claim 1, wherein: one side of the thermal power station (101) is provided with a support column (41), and the top of the support column (41) is fixedly connected with a detection box (47).

5. The wind, light, fire and heat energy storage multi-energy complementary system of claim 4, wherein: the upper surface mid-mounting of detection case (47) has air velocity transducer (206), the one side mid-mounting of detection case (47) has light intensity sensor (207).

6. The wind, light, fire and heat energy storage multi-energy complementary system of claim 3, wherein: the exhaust port of the steam energy storage device (201) is communicated with an air supply pipe (42), and one end of the air supply pipe (42) is communicated with an air inlet of a steam generator (203).

7. The wind, light, fire and heat energy storage multi-energy complementary system of claim 6, wherein: the middle part of the outer side wall of the air supply pipe (42) is communicated with a steam electromagnetic valve (43), and the middle part of the upper surface of the electric cabinet (204) is provided with a warning lamp (202).

8. The wind, light, fire, heat and energy storage multi-energy complementary system of claim 7, wherein: the signal output part of touch-control display screen (205), air velocity transducer (206) and illuminance sensor (207) passes through the signal input part of wire electric connection in PLC controller (45), the signal output part of PLC controller (45) passes through the signal input part of wire electric connection in touch-control display screen (205), the electric output part of PLC controller (45) passes through the electric input part of wire electric connection in relay (46), the electric output part of relay (46) passes through the electric input part of wire electric connection in steam solenoid valve (43) and warning light (202).

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