CN217031323U - Energy storage type multi-energy complementary heating system - Google Patents

Abstract

The utility model discloses an energy storage type multi-energy complementary heating system, and relates to the technical field of heating systems. The photovoltaic component is used for supplying power to the electric wall-hung boiler so as to realize that the electric wall-hung boiler supplies heat to the heating radiator; and an energy storage and insulation box is communicated between the electric wall-mounted boiler and the heating radiator and used for storing the heat energy left by the electric wall-mounted boiler after supplying heat to the heating radiator so as to supply heat to the heating radiator when the photovoltaic module is in power shortage. By arranging the photovoltaic module, the mains supply power grid, the electric wall-hung furnace, the energy storage heat insulation box and the heating radiator, the photovoltaic module is fully powered by the energy storage heat insulation box and the mains supply power grid, the mains supply power grid is used for supplying power when the photovoltaic module is in power shortage, the light energy is used as all weather as far as possible, heating cost is reduced, impact on the mains supply power grid is reduced, the influence on the environment is reduced, economic benefits are met, and the solar heating system has a wide application prospect.

Description

Energy storage type multi-energy complementary heating system

Technical Field

The utility model relates to the technical field of heating systems, in particular to an energy storage type multi-energy complementary heating system.

Background

The heating system is designed for buildings and cold-proof heating devices, so that the interior of the buildings can obtain proper temperature.

According to the heating area of 100 square meters, the installed capacity of about 10KW electric heating equipment is needed, the electricity consumption every day is about 100 degrees, the heating cost of residents is high, the residents use electricity and heat more at the same time (at night), the power grid power supply load is large in the section time, the power dispatching is not convenient, the power supply facility faults are easily caused, and the power generation equipment is mainly in a thermal power generation mode, carbon emission is easily generated, and the use demand cannot be met.

SUMMERY OF THE UTILITY MODEL

The utility model provides an energy storage type multi-energy complementary heating system, which aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: an energy storage type multi-energy complementary heating system comprises a photovoltaic module, an electric wall-mounted furnace and a heating radiator communicated with the electric wall-mounted furnace, wherein the photovoltaic module is used for supplying power to the electric wall-mounted furnace so as to realize that the electric wall-mounted furnace supplies heat to the heating radiator;

an energy storage insulation box is communicated between the electric wall-mounted boiler and the heating radiator and used for storing heat energy remained after the electric wall-mounted boiler supplies heat to the heating radiator so as to supply heat to the heating radiator when the photovoltaic module is in power shortage;

and the power transmission line of the photovoltaic module is connected to a mains supply power grid through a grid-connected box, and the electric energy of the photovoltaic module is injected into the mains supply power grid after the energy storage insulation can reaches the upper limit, so that the photovoltaic module supplies power to the electric wall-mounted boiler when the photovoltaic module is in power shortage.

Furthermore, an inverter is installed on a power transmission line between the photovoltaic module and the grid-connected box.

Furthermore, the electricity is connected with the room temperature controller that is used for detecting and controlling heating ambient temperature on the electricity hanging stove.

Furthermore, a first circulating pump is arranged on an input pipeline of the electric wall-mounted boiler, and an output pipeline of the electric wall-mounted boiler is connected with an input pipeline of a heating radiator.

Furthermore, an output pipeline of the heating radiator is communicated with an input pipeline of the electric wall-hung furnace, and the output pipeline of the heating radiator is provided with two first by-pass pipes and a first electromagnetic valve positioned between the two first by-pass pipes.

Furthermore, a second electromagnetic valve and a third electromagnetic valve are respectively arranged on the two first bypass pipes, and one ends of the two first bypass pipes, which are far away from the output pipeline of the heating radiator, are respectively communicated with the input end and the input end of the energy storage insulation box.

Furthermore, a circulating pump II which is positioned between the electromagnetic valve III and the energy storage and insulation box is arranged on the bypass pipe I provided with the electromagnetic valve III.

Furthermore, the output pipeline of the electric wall-mounted boiler is provided with two bypass pipes II and a solenoid valve IV positioned between the two bypass pipes II.

Furthermore, one end of each of the two bypass pipes II, which is far away from the output pipeline of the electric wall-mounted boiler, is respectively communicated with the input end and the output end of the energy storage insulation can.

Compared with the prior art, the utility model provides an energy storage type multi-energy complementary heating system which has the following beneficial effects:

according to the energy storage type multi-energy complementary heating system, the photovoltaic module, the mains supply power grid, the electric wall-hung furnace, the energy storage heat insulation box and the heating radiator are arranged, the power supply of the photovoltaic module is fully utilized through the energy storage heat insulation box and the mains supply power grid, the mains supply power grid is used for supplying power when the photovoltaic module is in power shortage, the light energy is used in all weather as far as possible, the heating cost is reduced, the impact on the mains supply power grid is reduced, the influence on the environment is reduced, the economic benefit is met, and the wide application prospect is achieved.

Drawings

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

FIG. 2 is a schematic diagram of the power transmission line of the photovoltaic module and the electric fireplace of the present invention;

fig. 3 is a schematic view of a connection pipeline between the electric wall-hanging stove and the heating radiator according to the present invention.

In the figure: 1. a photovoltaic module; 2. an inverter; 3. and a net cage; 4. a mains grid; 5. an electric wall-mounted boiler; 6. a first circulating pump; 7. a first electromagnetic valve; 8. an energy storage insulation can; 9. a second electromagnetic valve; 10. a third electromagnetic valve; 11. a second circulating pump; 12. a heating radiator; 13. a room temperature controller; 14. and a fourth electromagnetic valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-3, the utility model discloses an energy storage type multi-energy complementary heating system, which comprises a photovoltaic module 1, an electric wall-hung furnace 5 and a heating radiator 12 communicated with the electric wall-hung furnace 5, wherein the photovoltaic module 1 is used for supplying power to the electric wall-hung furnace 5 so as to realize that the electric wall-hung furnace 5 supplies heat to the heating radiator 12, and the photovoltaic module 1 is composed of at least one solar photovoltaic panel.

The communication has energy storage insulation can 8 between electric hanging stove 5 and the heating radiator 12 for the deposit remaining heat energy after electric hanging stove 5 supplies heat to heating radiator 12, with when photovoltaic module 1 is insufficient of electricity, to heating radiator 12 supplies heat.

The utility model discloses a solar energy heating system, including photovoltaic module 1, box with a net 3, electric wire netting 4, be used for energy storage insulation can 8 reaches the upper limit after on the power transmission line of photovoltaic module 1, will photovoltaic module 1's electric energy pours into electric wire netting 4 into, in order when photovoltaic module 1 is insufficient current, to electricity hanging stove 5 power supply, when the terminal demand that reaches of heating and energy storage insulation can 8 reach the capacity peak value, photovoltaic module 1's electric energy pours into to electric wire netting 4, forms one set of power generation system of constituteing by photovoltaic module 1 and electric wire netting 4, simultaneously when energy storage insulation can 8 energy reduces to the limit value and does not have solar light, leads to photovoltaic module 1 to be insufficient current, and electric wire netting 4 supplies electric wall boiler heating, forms one set of heating system of constituteing by electric wire netting 4, electric wall hanging stove 5 and heating radiator 12.

When the solar illumination is insufficient and the power generation power of the photovoltaic module 1 is insufficient, the photovoltaic module 1 and the commercial power grid 4 simultaneously supply power to the wall-mounted boiler 5 for heating, so that a set of heating system consisting of the photovoltaic module 1, the commercial power grid 4, the electric wall-mounted boiler 5 and a heating radiator 12 is formed.

Through the above steps, the light energy is used in all weather as much as possible, so that the purposes of reducing heating cost, reducing impact on a power grid and reducing influence on the environment are achieved, and the method contributes to the national double-carbon target.

Specifically, an inverter 2 is installed on a power transmission line between the photovoltaic module 1 and the grid-connected box 3, and direct current and alternating current are converted through the inverter 2, so that the voltage, the frequency and the phase are consistent with the height of a commercial power grid 4, and the grid-connected requirement is met.

Specifically, electricity is connected with room temperature controller 13 that is used for detecting and controlling heating ambient temperature on the electric hanging stove 5, controls electric hanging stove 5 through room temperature controller 13, has made things convenient for user operation.

Specifically, be provided with circulating pump 6 on the input pipeline of electricity hanging stove 5, the output pipeline of electricity hanging stove 5 is connected with the input pipeline of heating radiator 12, when solar light shines, photovoltaic module 1 generates electricity, has the demand when the heating end, and photovoltaic module 1's electric energy power supply hanging stove 5 heating to with heating radiator 12 in the heat energy transport, form one set of heating system who comprises photovoltaic module 1, electricity hanging stove 5 and heating radiator 12.

Specifically, an output pipeline of the heating radiator 12 is communicated with an input pipeline of the electric wall-mounted boiler 5, an output pipeline of the heating radiator 12 is provided with two first by-pass pipes and a first electromagnetic valve 7 positioned between the two first by-pass pipes, the two first by-pass pipes are respectively provided with a second electromagnetic valve 9 and a third electromagnetic valve 10, one ends of the two first by-pass pipes, which are far away from the output pipeline of the heating radiator 12, are respectively communicated with an input end and an input end of an energy storage insulation can 8, the first by-pass pipe provided with the third electromagnetic valve 10 is provided with a second circulating pump 11 positioned between the third electromagnetic valve 10 and the energy storage insulation can 8, the output pipeline of the electric wall-mounted boiler 5 is provided with two second by-pass pipes and a fourth electromagnetic valve 14 positioned between the two second by-pass pipes, one ends of the two second by-pass pipes, which are far away from the output pipeline of the electric wall-mounted boiler 5, are respectively communicated with the input end and the output end of the energy storage insulation can 8, referring to fig. 1, in field implementation, the pipeline connection layout is performed according to the flowing direction of the heating medium in the pipeline in fig. 1, when the heating end reaches the heating requirement, the photovoltaic module 1 is powered by electric energy to heat the wall-mounted boiler 5, and the heat energy outside the heating requirement is stored in the energy storage insulation box 8, so as to form an energy storage system consisting of the photovoltaic module 1, the electric wall-mounted boiler 5 and the energy storage insulation box 8, and when no sunlight exists, i.e. the photovoltaic module 1 is in power shortage, the heat energy stored in the energy storage insulation box 8 is utilized to supply heat to the heating radiator 12, so as to form a heating system consisting of the energy storage insulation box 8 and the heating radiator 12.

To sum up, the energy storage type multi-energy complementary heating system fully utilizes the power supply of the photovoltaic component 1 through the photovoltaic component 1, the commercial power grid 4, the electric wall-hung furnace 5, the energy storage insulation box 8 and the heating radiator 12 and fully utilizes the power supply of the photovoltaic component 1 through the energy storage insulation box 8 and the commercial power grid 4, the photovoltaic component 1 only uses the commercial power grid 4 to supply power when the power is lost, the light energy is used in all weather as far as possible, the purposes of reducing the heating cost, reducing the impact on the commercial power grid 4 and reducing the influence on the environment are achieved, the economic benefit is met, and the wide application prospect is achieved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a complementary heating system of energy storage formula multipotency source, includes photovoltaic module (1), electric hanging stove (5) and heating radiator (12) that are linked together with electric hanging stove (5), its characterized in that: the photovoltaic module (1) is used for supplying power to the electric wall-mounted boiler (5) so as to realize that the electric wall-mounted boiler (5) supplies heat to the heating radiator (12);

an energy storage and insulation box (8) is communicated between the electric wall-mounted boiler (5) and the heating radiator (12) and is used for storing the heat energy left after the electric wall-mounted boiler (5) supplies heat to the heating radiator (12) so as to supply heat to the heating radiator (12) when the photovoltaic module (1) is in power shortage;

the photovoltaic power generation system is characterized in that a power grid (4) is connected to a transmission line of the photovoltaic module (1) through a net cage (3) and used for injecting electric energy of the photovoltaic module (1) into the commercial power grid (4) after the energy storage heat insulation box (8) reaches an upper limit, so that the photovoltaic module (1) supplies power to the electric wall-mounted furnace (5) when the photovoltaic module (1) is in power shortage.

2. The energy-storage type multi-energy complementary heating system according to claim 1, wherein: an inverter (2) is installed on a power transmission line between the photovoltaic module (1) and the grid-connected box (3).

3. The energy-storage multi-energy complementary heating system according to claim 1, wherein: the electric wall-mounted boiler (5) is electrically connected with a room temperature controller (13) for detecting and controlling the heating ambient temperature.

4. The energy-storage type multi-energy complementary heating system according to claim 1, wherein: the circulating pump I (6) is arranged on an input pipeline of the electric wall-mounted boiler (5), and an output pipeline of the electric wall-mounted boiler (5) is connected with an input pipeline of a heating radiator (12).

5. The energy-storage type multi-energy complementary heating system according to claim 1, wherein: an output pipeline of the heating radiator (12) is communicated with an input pipeline of the electric wall-hung stove (5), and the output pipeline of the heating radiator (12) is provided with two first by-pass pipes and a first electromagnetic valve (7) positioned between the two first by-pass pipes.

6. The energy-storage type multi-energy complementary heating system according to claim 5, wherein: and the two first bypass pipes are respectively provided with a second electromagnetic valve (9) and a third electromagnetic valve (10), and one ends of the two first bypass pipes, which are far away from the output pipeline of the heating radiator (12), are respectively communicated with the input end and the input end of the energy storage insulation can (8).

7. The energy-storage multi-energy complementary heating system according to claim 6, wherein: and a circulating pump II (11) positioned between the electromagnetic valve III (10) and the energy storage and insulation box (8) is arranged on the bypass pipe I provided with the electromagnetic valve III (10).

8. The energy-storage multi-energy complementary heating system according to claim 1, wherein: and an output pipeline of the electric wall-mounted furnace (5) is provided with two second by-pass pipes and a fourth electromagnetic valve (14) positioned between the two second by-pass pipes.

9. The energy-storage type multi-energy complementary heating system according to claim 8, wherein: and one end of each of the two bypass pipes II, which is far away from the output pipeline of the electric wall-mounted boiler (5), is respectively communicated with the input end and the output end of the energy storage insulation can (8).

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