CN210089159U - Multi-energy complementary intelligent heat energy integrated control system - Google Patents

Abstract

The utility model relates to a belong to renewable energy utilization, flue gas waste heat recovery utilizes, the technical field of energy ladder utilization, in particular to complementary wisdom heat energy integrated control system of multipotency. The intelligent multi-energy complementary heat energy integrated control system comprises a solar water heater, a solar power generation system, a solar power storage system, a range hood, a multifunctional water tank, a first heat exchanger, a gas stove, a second heat exchanger, a first water storage tank, an air source heat pump, a swimming pool, a second water storage tank, a heater and a pressure release valve. The utility model discloses an ability integrated control system arrange, the waste heat that produces solar energy and kitchen range of very big limit utilizes, through the centralized control that can integrated control system arrange and the motorised valve simultaneously, carries out the centralized control to water supply system and adjusts the temperature, has realized that the temperature is complementary, heat energy is integrated.

Description

Multi-energy complementary intelligent heat energy integrated control system

Technical Field

The utility model relates to a belong to renewable energy utilization, flue gas waste heat recovery utilizes, the technical field of energy ladder utilization, in particular to complementary wisdom heat energy integrated control system of multipotency.

Background

The gas cooking stove is a kitchen utensil heated by direct fire with liquefied petroleum gas, coal gas, natural gas and other gas fuels, and comprises a single stove, a double stove and a multi-hole stove. When the gas stove works, gas enters the stove from the gas inlet pipe, enters the burner through the adjustment of the gas valve, and simultaneously mixes a part of air (the part of air is called primary air), the mixed gas is sprayed out from the fire hole of the burner and is ignited by the ignition device to form flame (the air required by the combustion is called secondary air), and the flame is used for heating the cooker arranged on the pot support. Most of the existing gas stoves directly discharge the burned smoke into the air, the smoke also contains a large amount of heat, and the heat of the oil smoke generated during cooking is not utilized, so that great waste is caused to the energy in the using process. When the flame heats the cooker, the flame radiates heat to the surroundings, particularly the temperature of the outer flame is higher, and the radiated heat is often neglected to be utilized by people.

Solar energy is used as a new energy, and has three characteristics compared with the conventional energy: firstly, the method comprises the following steps: it is the most abundant energy source available to humans. It is estimated that in the past 11 billion years, the sun has consumed 2% of its own energy. The product is enough for global human beings in the future, is used for billions of years, is inexhaustible and inexhaustible. Secondly, the method comprises the following steps: on the earth, solar energy is available anywhere, can be developed and utilized on site, has no transportation problem, and has more utilization value particularly for rural areas, islands and remote areas with inaccessible traffic. Thirdly, the method comprises the following steps: solar energy is a clean energy source. When the device is developed and used, waste residue, waste water and waste gas are not generated, noise is not generated, and ecological balance is not influenced. Absolutely does not cause pollution and public nuisance.

The existing multi-energy complementary intelligent heat energy integrated control system is required to fully utilize the waste heat and solar energy when the gas furnace is used so as to meet the adjustment of different temperature requirements of domestic water, water for swimming pools and the like.

Disclosure of Invention

Therefore, the utility model discloses just make in view of above-mentioned problem, the utility model aims to provide a complementary wisdom heat energy integrated control system of multipotency carries out make full use of to waste heat and solar energy when gas furnace uses to satisfy the regulation of different temperature demands such as domestic water, swimming pool water.

According to the technical scheme of the utility model, a multi-energy complementary intelligent heat energy integrated control system is provided, which comprises a solar water heater, a solar power generation system, a solar power storage system, a smoke exhaust ventilator, a multifunctional water tank, a first heat exchanger, a gas stove, a second heat exchanger, a first water storage tank, an air source heat pump, a swimming pool, a second water storage tank, a heater and a pressure release valve;

a multi-energy complementary intelligent heat energy integrated control system comprises a water supply pipeline I, a water supply pipeline II, a water supply pipeline III, a water supply pipeline IV, a water supply pipeline V, a water supply pipeline VI, a water supply pipeline VII, a water supply pipeline nine, a water supply pipeline ten, a water supply pipeline eleven, a water supply pipeline twelve, a water supply pipeline thirteen, a steam pipeline I, a steam pipeline II and a heat preservation pipe network;

a multi-energy complementary intelligent heat energy integrated control system comprises: the electric valve I, the electric valve II, the electric valve III, the electric valve IV, the electric valve V, the electric valve VI, the electric valve eight, the electric valve nine, the electric valve eleven and the electric valve fourteen;

a multi-energy complementary intelligent heat energy integrated control system comprises: the temperature sensor comprises a first temperature sensor, a second temperature sensor, a third temperature sensor, a fourth temperature sensor and a fifth temperature sensor;

the multifunctional water tank includes: the temperature control system comprises a heat preservation box, a temperature control water tank I, a temperature control water tank II, a temperature control water tank III, a temperature control water tank IV, a connecting pipe I, a connecting pipe II, a connecting pipe III, a connecting pipe IV, a connecting pipe V, a connecting pipe VI, an electric valve fifteen, an electric valve sixteen, an electric valve seventeen, an electric valve eighteen, an electric valve nineteen, an electric valve twenty, a temperature sensor six and a temperature sensor seven;

the solar power generation system generates power under the action of solar energy and is connected to a solar power storage system;

the solar energy power storage system supplies power to the heater, the air source heat pump and other equipment;

the first water supply pipeline guides tap water into the solar water heater through the control of the first electric valve;

the solar water heater heats water under the action of solar energy and guides the water to the inside of the temperature-adjusting water tank III under the action of the water supply pipeline II and the electric valve II;

the water supply pipeline is communicated with the electric valve III to guide tap water into the temperature-adjusting water tank II;

the water supply pipeline four-way is controlled by the electric valve four to guide tap water into the water supply pipeline eleven;

the gas stove is characterized in that a heating water tank is arranged in the gas stove, tap water is guided into the heating water tank of the gas stove through the control of a fifth electric valve by a fifth water supply pipeline, and when the gas stove is used, water in the internal heating water tank is guided into a second water storage tank through a thirteenth water supply pipeline;

a first heat exchanger is arranged in a smoke exhaust channel of the smoke exhaust ventilator, and a second heat exchanger is arranged in a smoke exhaust channel of the gas stove;

the water supply pipeline six guides tap water into the heat exchanger I under the control of the electric valve six, and then water in the heat exchanger I is guided into the heat exchanger II through the water supply pipeline seven after heat exchange;

the water in the second heat exchanger is subjected to heat exchange and then flows out in two paths, one path of water flows into the second water storage tank through the twelve water supply pipelines, and the other path of water flows into the first water storage tank through the eight water supply pipelines under the control of the eight electric valve;

the first water storage tank flows into the swimming pool under the control of the electric valve nine through a water supply pipeline nine;

the air source heat pump heats tap water and then flows into the first water storage tank through the water supply pipeline;

the temperature-regulating water tank four-way water supply pipeline eleven is controlled by an electric valve eleven to flow into the swimming pool;

a heater is arranged inside the water storage tank II, and a pressure release valve is arranged on the water storage tank II;

a heat preservation pipe network is arranged around the swimming pool to preserve heat of the outer wall surface of the swimming pool;

high-temperature steam in the second water storage tank flows out in two ways through the pressure release valve, one way is led into the heat preservation pipe network through the steam pipeline, and the other way is led into the fourth temperature-regulating water tank through the steam pipeline to heat the interior of the fourth temperature-regulating water tank;

a first temperature sensor is arranged inside the first water storage tank, a second temperature sensor is arranged inside the air source heat pump, a third temperature sensor is arranged inside the swimming pool, a fourth temperature sensor is arranged inside the second water storage tank, and a fifth temperature sensor is arranged in a heating water tank of the gas stove;

a temperature-regulating water tank I, a temperature-regulating water tank II, a temperature-regulating water tank III and a temperature-regulating water tank IV are arranged in the heat-insulating box;

the temperature-regulating water tank I is arranged on the left side of the temperature-regulating water tank II, the temperature-regulating water tank IV is arranged below the temperature-regulating water tank II, the temperature-regulating water tank III is arranged on the left side of the temperature-regulating water tank IV, and the temperature-regulating water tank III is arranged below the temperature-regulating water tank I;

the first temperature-regulating water tank is communicated with a second temperature-regulating water tank through a fourth connecting pipe and a third connecting pipe, the third temperature-regulating water tank is communicated with the fourth temperature-regulating water tank through a fifth connecting pipe and a sixth connecting pipe, the first temperature-regulating water tank is communicated with the third temperature-regulating water tank through the first connecting pipe, and the second temperature-regulating water tank is communicated with the fourth temperature-regulating water tank through the second connecting pipe;

the electric valve seventeen is arranged in the connecting pipe IV and controls the on-off condition of the connecting pipe IV, the electric valve eighteen is arranged in the connecting pipe III and controls the on-off condition of the connecting pipe III, the electric valve nineteen is arranged in the connecting pipe V and controls the on-off condition of the connecting pipe V, the electric valve twenty is arranged in the connecting pipe VI and controls the on-off condition of the connecting pipe VI, the electric valve fifteen is arranged in the connecting pipe I and controls the on-off condition of the connecting pipe I, and the electric valve sixteen is arranged in the connecting pipe II and controls the on-off condition of the connecting pipe II;

the solar power generation system, the solar power storage system, the air source heat pump, the heater, the electric valve I, the electric valve II, the electric valve III, the electric valve IV, the electric valve VI, the electric valve VIII, the electric valve IX, the electric valve eleven, the electric valve fourteen, the temperature sensor I, the temperature sensor II, the temperature sensor III, the temperature sensor IV, the temperature sensor V, the electric valve fifteen, the electric valve sixteen, the electric valve seventeen, the electric valve eighteen, the electric valve nineteen, the electric valve twenty, the temperature sensor VI and the temperature sensor seventeen are all connected into the centralized control system and are coordinately controlled by the centralized control system;

the electric valve I, the electric valve II, the electric valve III, the electric valve IV, the electric valve V, the electric valve VI, the electric valve VIII, the electric valve IX, the electric valve XI, the electric valve fourteen, the electric valve fifteen, the electric valve sixteen, the electric valve seventeen, the electric valve eighteen, the electric valve nineteen and the electric valve twenty are all used for controlling the on-off and flow of fluid and have the functions of check valves.

In one embodiment, tap water is introduced into the first water storage tank.

In one embodiment, the other end of the insulated piping network opposite to the connection relief valve is connected to the swimming pool.

In one embodiment, the multipurpose tank is positioned above the pool.

In one embodiment, the first temperature-regulating water tank and the second temperature-regulating water tank are provided with pressure relief valves.

In one embodiment, the water supply pipeline eight is connected to one end of the second heat exchanger far away from the flue gas source, and the upper end of the second heat exchanger is relatively positioned in the temperature drop area of the flue gas.

In one embodiment, the water supply pipeline twelve is connected to one end of the second heat exchanger close to the flue gas source, and the lower end of the second heat exchanger is relatively positioned in the high-temperature area of the flue gas.

The utility model has the advantages as follows:

1. through the arrangement of the integrated control system, the solar energy and the waste heat generated by the stove are utilized to the maximum extent.

2. The water supply system is subjected to centralized control and temperature regulation through the arrangement of the integrated control system and the centralized control of the electric valves, so that temperature complementation and heat energy integration are realized.

Drawings

Fig. 1 is a view of the overall structure of the system of the present invention.

Fig. 2 is a second view of the overall system structure of the present invention.

Fig. 3 is a third view of the overall structure of the system of the present invention.

Fig. 4 is a fourth view of the overall structure of the system of the present invention.

Fig. 5 is a first view of the system structure of the present invention.

Fig. 6 is a second system part structure view of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are easily implemented by those having ordinary skill in the art to which the present invention pertains. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In addition, for the purpose of more clearly describing the present invention, parts not connected with the present invention will be omitted from the drawings.

As shown in figure 1, the multi-energy complementary intelligent heat energy integrated control system comprises a solar water heater 1, a solar power generation system 2, a solar power storage system 3, a smoke exhaust ventilator 4, a multifunctional water tank 5, a first heat exchanger 6, a gas stove 7, a second heat exchanger 8, a first water storage tank 9, an air source heat pump 10, a swimming pool 11, a second water storage tank 12, a heater 13 and a pressure release valve 14;

as shown in fig. 2, a multi-energy complementary intelligent heat energy integrated control system comprises a water supply pipeline I21, a water supply pipeline II 22, a water supply pipeline III 23, a water supply pipeline IV 24, a water supply pipeline V25, a water supply pipeline VI 26, a water supply pipeline VII 27, a water supply pipeline VIII 28, a water supply pipeline IX 29, a water supply pipeline XI 210, a water supply pipeline XI 211, a water supply pipeline VII 212, a water supply pipeline XII 213, a steam pipeline I214, a steam pipeline II 215 and a heat preservation pipeline network 216;

as shown in fig. 3, a multi-energy complementary intelligent heat energy integrated control system includes: electric valve one 31, electric valve two 32, electric valve three 33, electric valve four 34, electric valve five 35, electric valve six 36, electric valve eight 38, electric valve nine 39, electric valve eleven 311 and electric valve fourteen 314;

as shown in fig. 4, a multi-energy complementary intelligent heat energy integrated control system includes: a first temperature sensor 41, a second temperature sensor 42, a third temperature sensor 43, a fourth temperature sensor 44 and a fifth temperature sensor 45;

as shown in fig. 5 and 6, the multi-functional water tank 5 includes: the temperature control system comprises an incubator 51, a first temperature control water tank 52, a second temperature control water tank 53, a third temperature control water tank 54, a fourth temperature control water tank 55, a first connecting pipe 56, a second connecting pipe 57, a third connecting pipe 58, a fourth connecting pipe 59, a fifth connecting pipe 510, a sixth connecting pipe 511, a fifteenth electric valve 512, a sixteenth electric valve 513, a seventeenth electric valve 514, an eighteen electric valve 515, a nineteen electric valve 516, a twenty-twenty electric valve 517, a sixth temperature sensor 518 and a seventh temperature sensor 519;

the solar power generation system 2 generates power under the action of solar energy and is connected to the solar power storage system 3;

the solar power storage system 3 supplies power to the heater 13, the air source heat pump 10 and other equipment;

the water supply pipeline I21 guides tap water into the solar water heater 1 under the control of the electric valve I31;

the solar water heater 1 heats water under the action of solar energy and guides the water to the inside of the temperature-adjusting water tank III 54 under the action of the water supply pipeline II 22 and the electric valve II 32;

the third water supply pipeline 23 guides tap water into the second temperature-regulating water tank 53 under the control of the third electric valve 33;

the water supply pipeline four 24 guides tap water into a water supply pipeline eleven 211 through the control of an electric valve four 34;

a heating water tank is arranged in the gas stove 7, tap water is guided into the heating water tank of the gas stove 7 through the control of the electric valve five 35 by the water supply pipeline five 25, and when the gas stove 7 is used, water in the internal heating water tank is guided into the water storage tank two 12 through the water supply pipeline thirteen 213;

a first heat exchanger 6 is arranged in a smoke exhaust channel of the smoke exhaust ventilator 4, and a second heat exchanger 8 is arranged in a smoke exhaust channel of the gas stove 7;

the water supply pipeline six 26 guides tap water into the heat exchanger I6 under the control of the electric valve six 36, and then the water in the heat exchanger I6 is subjected to heat exchange and then is guided into the heat exchanger II 8 through the water supply pipeline seven 27;

the water in the second heat exchanger 8 is subjected to heat exchange and then flows out in two paths, one path flows into the second water storage tank 12 through a water supply line twelve 212, and the other path flows into the first water storage tank 9 through a water supply line eight 28 under the control of an electric valve eight 38;

the first water storage tank 9 flows down to the swimming pool 11 through a water supply pipeline nine 29 under the control of an electric valve nine 39;

the air source heat pump 10 heats tap water and then flows into the first water storage tank 9 through the water supply pipeline ten 210;

the fourth temperature-regulating water tank 55 flows into the swimming pool 11 through a water supply pipeline eleven 211 under the control of an electric valve eleven 311;

a heater 13 is arranged inside the second water storage tank 12, and a pressure release valve 14 is arranged on the second water storage tank 12;

a heat preservation pipe network 216 is arranged around the swimming pool 11 to preserve heat of the outer wall surface of the swimming pool 11;

high-temperature steam in the second water storage tank 12 flows out in two ways through the pressure release valve 14, one way is led into the heat preservation pipe network 216 through the second steam pipeline 215, and the other way is led into the fourth temperature-adjusting water tank 55 through the first steam pipeline 214 to heat the interior of the fourth temperature-adjusting water tank 55;

a first temperature sensor 41 is arranged inside the first water storage tank 9, a second temperature sensor 42 is arranged inside the air source heat pump 10, a third temperature sensor 43 is arranged inside the swimming pool 11, a fourth temperature sensor 44 is arranged inside the second water storage tank 12, and a fifth temperature sensor 45 is arranged in a heating water tank of the gas stove 7;

a first temperature-regulating water tank 52, a second temperature-regulating water tank 53, a third temperature-regulating water tank 54 and a fourth temperature-regulating water tank 55 are arranged in the heat-insulating box 51;

the first temperature-adjusting water tank 52 is arranged on the left side of the second temperature-adjusting water tank 53, the fourth temperature-adjusting water tank 55 is arranged below the second temperature-adjusting water tank 53, the third temperature-adjusting water tank 54 is arranged on the left side of the fourth temperature-adjusting water tank 55, and the third temperature-adjusting water tank 54 is arranged below the first temperature-adjusting water tank 52;

the first temperature-regulating water tank 52 is communicated with a second temperature-regulating water tank 53 through a fourth connecting pipe 59 and a third connecting pipe 58, the third temperature-regulating water tank 54 is communicated with a fourth temperature-regulating water tank 55 through a fifth connecting pipe 510 and a sixth connecting pipe 511, the first temperature-regulating water tank 52 is communicated with the third temperature-regulating water tank 54 through a first connecting pipe 56, and the second temperature-regulating water tank 53 is communicated with the fourth temperature-regulating water tank 55 through a second connecting pipe 57;

the electric valve seventeen 514 is arranged in the connecting pipe four 59 and controls the on-off condition of the connecting pipe four 59, the electric valve eighteen 515 is arranged in the connecting pipe three 58 and controls the on-off condition of the connecting pipe three 58, the electric valve nineteen 516 is arranged in the connecting pipe five 510 and controls the on-off condition of the connecting pipe five 510, the electric valve twenty 517 is arranged in the connecting pipe six 511 and controls the on-off condition of the connecting pipe six 511, the electric valve fifteen 512 is arranged in the connecting pipe one 56 and controls the on-off condition of the connecting pipe one 56, and the electric valve sixteen 513 is arranged in the connecting pipe two 57 and controls the on-off condition of the connecting pipe two 57;

the solar power generation system 2, the solar power storage system 3, the air source heat pump 10, the heater 13, the electric valve I31, the electric valve II 32, the electric valve III 33, the electric valve IV 34, the electric valve V35, the electric valve VI 36, the electric valve VIII 38, the electric valve VII 39, the electric valve IV 311, the electric valve IV 314, the temperature sensor I41, the temperature sensor II 42, the temperature sensor III 43, the temperature sensor IV 44, the temperature sensor V45, the electric valve V512, the electric valve V513, the electric valve VII 514, the electric valve VII 515, the electric valve VII, the temperature sensor VI 518 and the temperature sensor VII 519 are all connected into a centralized control system and are coordinately controlled by the centralized control system;

the electric valve I31, the electric valve II 32, the electric valve III 33, the electric valve IV 34, the electric valve V35, the electric valve VI 36, the electric valve VIII 38, the electric valve VII 39, the electric valve XI 311, the electric valve XIIC 314, the electric valve fifteen 512, the electric valve XI 513, the electric valve VII 514, the electric valve VII 515, the electric valve nineteen 516 and the electric valve VII 517 are all used for controlling the on-off and flow of fluid, and have the function of a one-way valve.

Preferably, as an implementation mode, tap water is introduced into the first water storage tank 9, and the arrangement enables the tap water to adjust the temperature of the water in the first water storage tank 9, so that the use is convenient for users.

Preferably, as an implementation mode, the other end of the thermal insulation pipe network 216 opposite to the connection pressure release valve 14 is connected to the swimming pool 11, and the condensed water of the steam and the residual temperature of the condensed water are fully utilized to heat the swimming pool water.

Preferably, as an embodiment, the multi-functional tank 5 is disposed above the pool 11, and this arrangement utilizes the principle of communicating vessels to supply water to the pool 11.

Preferably, as an implementation mode, the first temperature-adjusting water tank 52 and the second temperature-adjusting water tank 53 are provided with pressure relief valves, and the pressure relief valves are opened to relieve pressure when the pressure inside the first temperature-adjusting water tank 52 and the second temperature-adjusting water tank 53 reaches a set value.

Preferably, as an implementation mode, the water supply pipeline eight 28 is connected to one end of the second heat exchanger 8 far away from the flue gas source, the upper end of the second heat exchanger 8 is relatively positioned in a temperature drop area of the flue gas, and the arrangement enables warm water to be obtained in the water supply pipeline eight 28.

Preferably, as an implementation mode, the water supply pipeline twelve 212 is connected to one end of the heat exchanger two 8 close to the flue gas source, and the lower end of the heat exchanger two 8 is relatively positioned in the high-temperature area of the flue gas, so that water with higher temperature is obtained in the water supply pipeline twelve 212.

The utility model discloses the theory of operation:

① the solar power generation system 2 generates electricity and stores the electricity in the solar power storage system 3, and the electricity supplies the heater 13, the air source heat pump 10 and other devices.

② electric valve I31 is opened, tap water is led into the solar water heater 1 through the water supply pipeline I21, the solar water heater 1 heats the tap water in the solar water heater 1 under the action of solar energy, the electric valve II 32 is opened, hot water in the solar water heater 1 is led into the temperature regulating water tank III 54 through the water supply pipeline II 22, the temperature sensor seven 519 detects the temperature in the temperature regulating water tank III 54, when the temperature is higher than the required temperature:

in the first case: when the required warm water amount is less, the electric valve III 33, the electric valve sixteen 513, the electric valve nineteen 516 and the electric valve twenty 517 are opened, the tap water cools the water in the warming water tank III 54, and when the required water temperature is reached, the electric valve III 33, the electric valve sixteen 513, the electric valve nineteen 516 and the electric valve twenty 517 are closed.

In the second case: when the required water temperature is large, the electric valve three 33, the electric valve fifteen 512, the electric valve seventeen 514 and the electric valve eighteen 515 are opened, the tap water cools the water in the temperature regulating water tank three 54 and the temperature regulating water tank one 52, and when the required water temperature is reached, the electric valve three 33, the electric valve fifteen 512, the electric valve seventeen 514 and the electric valve eighteen 515 are closed.

In the third case: when the required warm water amount is large, the electric valve III 33, the electric valve fifteen 512, the electric valve sixteen 513, the electric valve seventeen 514 and the electric valve eighteen 515 are opened, and tap water adjusts the temperature of water in the temperature adjusting water tank I52, the temperature adjusting water tank II 53, the temperature adjusting water tank III 54 and the temperature adjusting water tank IV 55.

③ electric valve five 35 is opened, tap water is led into the heating water tank of the gas stove 7 through water supply pipe five, when the gas stove 7 is in use, water in the internal heating water tank is led into the water storage tank two 12 through water supply pipe thirteen 213. electric valve six 36 is opened, tap water is led into the heat exchanger one 6 through water supply pipe six 26, then water in the heat exchanger one 6 is led into the heat exchanger two 8 through water supply pipe seven 27 after heat exchange, when the electric valve eight 38 is closed, tap water passing through the heat exchanger two 8 flows into the water storage tank two 12 through water supply pipe twelve 212, when the electric valve eight 38 is opened, a part of tap water passing through the heat exchanger two 8 enters the water storage tank one 9 to adjust the temperature of water in the water storage tank one 9.

④ when the swimming pool 11 needs to supply warm water, the electric valve eleven 311 is opened, warm water in the temperature regulating water tank four 55 is introduced into the swimming pool 11 through the water supply pipe eleven 211, at this time, if the warm water in the temperature regulating water tank four 55 is still higher than the temperature required by the swimming pool 11, the electric valve four 34 is opened, tap water is introduced into the water supply pipe eleven 211 through the water supply pipe four 24 to regulate the temperature of the water therein, meanwhile, the swimming pool has another water supply path, the electric valve nine 39 is opened, warm water in the water storage tank one 9 is introduced into the swimming pool 11 through the water supply pipe nine 29.

⑤ when water is needed in the first water storage tank 9, the solar energy storage system 3 supplies power to the air source heat pump 10, and tap water heats the water under the action of the air source heat pump 10 and is guided into the first water storage tank 9 through the water supply pipeline 210.

⑥ when the water in the second water storage tank 12 is boiled water, when the temperature is lower than the set value, the solar energy electric power storage system 3 supplies power to the heater 13 to heat the water in the second water storage tank 12. when the pressure in the eleventh water supply pipeline 211 reaches the set value, the pressure release valve 14 is opened, when the fourteen electric valve 314 is closed, the steam led out by the pressure release valve 14 is led into the heat preservation pipe network 216 through the second steam pipeline 215 to preserve the heat around the swimming pool 11, when the fourteen electric valve 314 is opened, one end of the heat preservation pipe network 216 is closed, the steam led out by the pressure release valve 14 is led into the fourth temperature regulation water tank 55 through the first steam pipeline 214 to heat the water in the fourth temperature regulation water tank 55.

Claims (7)

1. A multi-energy complementary intelligent heat energy integrated control system comprises a solar water heater (1), a solar power generation system (2), a solar power storage system (3), a smoke exhaust ventilator (4), a multifunctional water tank (5), a first heat exchanger (6), a gas stove (7), a second heat exchanger (8), a first water storage tank (9), an air source heat pump (10), a swimming pool (11), a second water storage tank (12), a heater (13), a pressure release valve (14), a first water supply pipeline (21), a second water supply pipeline (22), a third water supply pipeline (23), a fourth water supply pipeline (24), a fifth water supply pipeline (25), a sixth water supply pipeline (26), a seventh water supply pipeline (27), an eighth water supply pipeline (28), a ninth water supply pipeline (29), a tenth water supply pipeline (210), a eleventh water supply pipeline (211), a twelfth water supply pipeline (212), a thirteenth water supply pipeline (, The system comprises a first steam pipeline (214), a second steam pipeline (215), a heat-preservation pipe network (216), a first electric valve (31), a second electric valve (32), a third electric valve (33), a fourth electric valve (34), a fifth electric valve (35), a sixth electric valve (36), an eighth electric valve (38), a ninth electric valve (39), an eleventh electric valve (311), a fourteenth electric valve (314), a first temperature sensor (41), a second temperature sensor (42), a third temperature sensor (43), a fourth temperature sensor (44) and a fifth temperature sensor (45);

the method is characterized in that: the multifunctional water tank (5) comprises: the temperature control system comprises a heat preservation box (51), a first temperature control water tank (52), a second temperature control water tank (53), a third temperature control water tank (54), a fourth temperature control water tank (55), a first connecting pipe (56), a second connecting pipe (57), a third connecting pipe (58), a fourth connecting pipe (59), a fifth connecting pipe (510), a sixth connecting pipe (511), a fifteenth electrically operated valve (512), a sixteenth electrically operated valve (513), a seventeenth electrically operated valve (514), an eighteen electrically operated valve (515), a nineteen electrically operated valve (516), a twenty electrically operated valve (517), a sixth temperature sensor (518) and a seventh temperature sensor (519;

the solar power generation system (2) generates power under the action of solar energy and is connected to the solar power storage system (3);

the solar energy power storage system (3) supplies power to the heater (13), the air source heat pump (10) and other equipment;

the water supply pipeline I (21) guides tap water into the solar water heater (1) through the control of the electric valve I (31);

the solar water heater (1) heats water under the action of solar energy and guides the water to the inside of a temperature-adjusting water tank III (54) under the action of a water supply pipeline II (22) and an electric valve II (32);

the water supply pipeline III (23) guides tap water into the temperature-adjusting water tank II (53) through the control of the electric valve III (33);

the fourth water supply pipeline (24) guides tap water into the eleventh water supply pipeline (211) through the control of the fourth electric valve (34);

a heating water tank is arranged in the gas stove (7), tap water is guided into the heating water tank of the gas stove (7) through the control of an electric valve five (35) by the water supply pipeline five (25), and when the gas stove (7) is used, water in the internal heating water tank is guided into a water storage tank two (12) through a water supply pipeline thirteen (213);

a first heat exchanger (6) is arranged in a smoke exhaust channel of the smoke exhaust ventilator (4), and a second heat exchanger (8) is arranged in a smoke exhaust channel of the gas stove (7);

the water supply pipeline six (26) guides tap water into the heat exchanger I (6) through the control of the electric valve six (36), and then water in the heat exchanger I (6) is guided into the heat exchanger II (8) through the water supply pipeline seven (27) after heat exchange;

the water in the second heat exchanger (8) is subjected to heat exchange and then flows out in two paths, one path flows into the second water storage tank (12) through a water supply pipeline twelve (212), and the other path flows into the first water storage tank (9) through a water supply pipeline eight (28) under the control of an electric valve eight (38);

the first water storage tank (9) flows down into the swimming pool (11) through a water supply pipeline nine (29) under the control of an electric valve nine (39);

the air source heat pump (10) heats tap water and then flows into the first water storage tank (9) through the water supply pipeline (210);

the temperature-regulating water tank IV (55) flows into the swimming pool (11) through a water supply pipeline IV (211) under the control of an electric valve IV (311);

a heater (13) is arranged inside the second water storage tank (12), and a pressure release valve (14) is arranged on the second water storage tank (12);

the periphery of the swimming pool (11) is provided with a heat-insulating pipe network (216) for insulating the outer wall surface of the swimming pool (11);

high-temperature steam in the water storage tank II (12) flows out in two ways through the pressure release valve (14), one way is led into the heat preservation pipe network (216) through the steam pipeline II (215), and the other way is led into the temperature regulation water tank IV (55) through the steam pipeline I (214) to heat the interior of the temperature regulation water tank IV (55);

a first temperature sensor (41) is arranged inside the first water storage tank (9), a second temperature sensor (42) is arranged inside the air source heat pump (10), a third temperature sensor (43) is arranged inside the swimming pool (11), a fourth temperature sensor (44) is arranged inside the second water storage tank (12), and a fifth temperature sensor (45) is arranged in a heating water tank of the gas stove (7);

a first temperature-regulating water tank (52), a second temperature-regulating water tank (53), a third temperature-regulating water tank (54) and a fourth temperature-regulating water tank (55) are arranged in the heat-insulating box (51);

the first temperature-regulating water tank (52) is arranged on the left side of the second temperature-regulating water tank (53), the fourth temperature-regulating water tank (55) is arranged below the second temperature-regulating water tank (53), the third temperature-regulating water tank (54) is arranged on the left side of the fourth temperature-regulating water tank (55), and the third temperature-regulating water tank (54) is arranged below the first temperature-regulating water tank (52);

the first temperature-regulating water tank (52) is communicated with the second temperature-regulating water tank (53) through a fourth connecting pipe (59) and a third connecting pipe (58), the third temperature-regulating water tank (54) is communicated with the fourth temperature-regulating water tank (55) through a fifth connecting pipe (510) and a sixth connecting pipe (511), the first temperature-regulating water tank (52) is communicated with the third temperature-regulating water tank (54) through a first connecting pipe (56), and the second temperature-regulating water tank (53) is communicated with the fourth temperature-regulating water tank (55) through a second connecting pipe (57);

the electric valve seventeen (514) is arranged in the connecting pipe four (59) and controls the on-off condition of the connecting pipe four (59), the electric valve eighteen (515) is arranged in the connecting pipe three (58) and controls the on-off condition of the connecting pipe three (58), the electric valve nineteen (516) is arranged in the connecting pipe five (510) and controls the on-off condition of the connecting pipe five (510), the electric valve twenty (517) is arranged in the connecting pipe six (511) and controls the on-off condition of the connecting pipe six (511), the electric valve fifteen (512) is arranged in the connecting pipe one (56) and controls the on-off condition of the connecting pipe one (56), and the electric valve sixteen (513) is arranged in the connecting pipe two (57) and controls the on-off condition of the connecting pipe two (57);

the solar power generation system (2), the solar power storage system (3), the air source heat pump (10), the heater (13), the electric valve I (31), the electric valve II (32), the electric valve III (33), the electric valve IV (34), the electric valve V (35), the electric valve VI (36), the electric valve VIII (38), the electric valve VIII (39), the electric valve eleven (311) and the electric valve fourteen (314), a first temperature sensor (41), a second temperature sensor (42), a third temperature sensor (43), a fourth temperature sensor (44), a fifth temperature sensor (45), a fifteenth electric valve (512), a sixteenth electric valve (513), a seventeenth electric valve (514), an eighteenth electric valve (515), a nineteen electric valve (516), a twenty electric valve (517), a sixth temperature sensor (518) and a seventh temperature sensor (519) are all connected into the centralized control system and are coordinately controlled by the centralized control system;

the electric valve I (31), the electric valve II (32), the electric valve III (33), the electric valve IV (34), the electric valve V (35), the electric valve VI (36), the electric valve VIII (38), the electric valve VII (39), the electric valve XI (311), the electric valve XIII (314), the electric valve fifteen (512), the electric valve XI (513), the electric valve VII (514), the electric valve eighteen (515), the electric valve nineteen (516) and the electric valve VII (517) are all used for controlling the on-off and flow of fluid and have a function of a one-way valve.

2. The system of claim 1, wherein the intelligent integrated control system comprises: tap water is led into the first water storage tank (9).

3. The system of claim 1, wherein the intelligent integrated control system comprises: the other end of the heat-preservation pipe network (216) opposite to the connecting pressure release valve (14) is connected into the swimming pool (11).

4. The system of claim 1, wherein the intelligent integrated control system comprises: the multifunctional water tank (5) is arranged above the swimming pool (11).

5. The system of claim 1, wherein the intelligent integrated control system comprises: and the first temperature regulating water tank (52) and the second temperature regulating water tank (53) are provided with pressure relief valves.

6. The system of claim 1, wherein the intelligent integrated control system comprises: and the water supply pipeline eight (28) is connected to one end of the heat exchanger II (8) far away from the flue gas source, and the upper end of the heat exchanger II (8) is relatively positioned in a flue gas temperature reduction area.

7. The system of claim 1, wherein the intelligent integrated control system comprises: and the water supply pipeline twelve (212) is connected to one end of the second heat exchanger (8) close to the flue gas source, and the lower end of the second heat exchanger (8) is relatively positioned in a high-temperature area of the flue gas.

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