KR20140123246A - Smart Energy Storage System of High-rise Buildings, Renewable Energy Used to Drive The Inverter Pump and How to Use - Google Patents

Abstract

The smart energy storage system and the utilization method using the inverter pump driven by the renewable energy of the high-rise buildings comply with the characteristics of the smart grid having the different price system according to the time, And the energy is converted into electric power in a time zone where the electric power charge is high, so that there is an effect of saving a reasonable energy use.
In addition, the power is stored in the form of location energy in the time zone (late night, morning) where the power supply capacity is relatively available during the peak power period (summer, winter) ), The total power demand peak can be smoothed.
In addition, the present invention has the effect of improving the inefficiency caused by the operation of the cogeneration system with the partial load in order to prevent the production of surplus power in the absence of the conventional power storage means.
The present invention has the effect of contributing to improvement of the spreadability of new and renewable energy technology and expansion of supply of new and renewable energy by providing a function of storing a renewable energy source generated intermittently using a power storage device for a predetermined period and using it as a constant output .
The present invention relates to a power supply control system for a power plant, comprising a power supply unit for supplying thermal energy or electricity, a power control unit for driving the inverter pump by voltage control and frequency conversion of the supplied electricity, a rooftop storage tank installed on the roof of the building for storing water, An inverter pump which is driven by a power source and pumps water in the underground tank and stores it as a rooftop storage tank; a hot water supply and heating unit that supplies hot water or heating to the building by receiving thermal energy from a power supply unit; An underground tank for supplying water to the hot water supply and heating section, a pumped storage section for dropping water from the roof storage tank by pumping water, a power supply section 100, a power control section, a hot water supply and heating section, And a control unit for increasing the efficiency.

Description

Technical Field [0001] The present invention relates to a smart energy storage system using an inverter pump driven by renewable energy of a high-rise building,

The present invention relates to a smart energy storage system using an inverter pump driven by renewable energy of a high-rise building, and a method of using the energy storage system, and a method of storing water in a storage tank on the roof using renewable energy (wind, sunlight) In order to improve the inefficiency caused by the inconsistency of energy production and demand such as the water is dropped and water is pumped and the water stored in the roof storage tank is heated to be used as hot water in summer and hot water and heating in winter, The present invention relates to a smart energy storage system using an inverter pump driven by renewable energy, and a utilization method thereof.

Generally, in the hot summer or the cold winter, power supply is not smooth enough to reach a peak power demand especially in downtown areas where buildings are concentrated. However, it is difficult to increase the power generation in accordance with the rapid increase of the electric power demand or construct a power plant corresponding to the shortage of electric power.

In urban areas where demand for electric power is large, electric power demand and supply are unbalanced, but partial power generation such as cogeneration power generation is used.

In addition, renewable energy, which has intermittent energy (wind, solar) production characteristics, is difficult to respond to the demands of major demanders who need immediate response when demand is generated, and thus it is difficult to supply the market.

Therefore, the smart energy storage system and the utilization method using the inverter pump driven by the renewable energy of the high-rise building of the present invention are efficient and cheap to use the electric power stored in the expensive electric power charge area And to provide a large-scale power storage and utilization system with a stable scale or more.

In addition, the present invention has an object to provide an efficient system for operating a self-power storage system when a distributed power source is operated in a high-rise building and the connection with a national power grid network is not possible.

In order to accomplish the above object, the present invention is implemented by the following embodiments.

A power supply control unit for driving the inverter pump by voltage control and frequency conversion of the supplied electricity, a rooftop storage tank installed on the roof of the building for storing water, and a power supply unit An inverter pump that pumps the water in the underground tank to store it as a roof storage tank, a hot water supply and heating unit that supplies hot water to the building by receiving thermal energy from the power supply unit, a roof storage tank, An underground tank for supplying water to the heating unit, a pumped-water generating unit for pumping water from the roof storage tank, and a control unit for controlling the power supply unit, the power supply control unit, the hot water supply and heating unit, and the pumped- .

The smart energy storage system and the utilization method using the inverter pump driven by the renewable energy of the high-rise buildings comply with the characteristics of the smart grid having the different price system according to the time, And the energy stored in the time zone in which the electric power rate is high is converted into electric power, thereby realizing a reduction in energy consumption.

In addition, the power is stored in the form of location energy in the time zone (late night, morning) where the power supply capacity is relatively available during the peak power period (summer, winter) ), The total power demand peak can be smoothed.

In addition, the present invention has an effect of improving the inefficiency occurring in the cogeneration when the cogeneration power is operated as a partial load in order to prevent the production of surplus power in the absence of the conventional power storage means.

In addition, the present invention provides an energy storage system capable of storing a renewable energy source generated intermittently using a power storage device for a predetermined period of time and using it as a constant output, thereby contributing to improving the spreadability of renewable energy technology .

1 is a structural diagram of a smart energy storage system and a utilization method using an inverter pump driven by renewable energy of a high-rise building of the present invention.
2 is a schematic diagram of an independent operation mode of a conventional renewable energy generation system.
3 is a structural diagram showing a cooling / heating system flow chart in a general cogeneration system.
4 is a schematic structural view of a system-linked operation mode of a conventional renewable energy generation system.
5 is an embodiment showing a distributed power distribution system in a distributed power source.
6 is a chart showing the potential for further realization of renewable energy by country.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In addition, although the term used in the present invention is selected as a general term that is widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, since the meaning is described in detail in the description of the relevant invention, It is to be understood that the present invention should be grasped as a meaning of a term that is not a name of the present invention. Further, in describing the embodiments, descriptions of technical contents which are well known in the technical field to which the present invention belongs and which are not directly related to the present invention will be omitted. This is for the sake of clarity of the present invention without omitting the unnecessary explanation.

1 is a view for explaining a smart energy storage system and a utilization method using an inverter pump driven by renewable energy of a high-rise building according to the present invention.

The present invention, as shown in Figure 1,

A power supply unit 100 for supplying thermal energy or electricity;

A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;

A roof storage tank 300 installed on the roof of the building for storing water;

An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;

A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;

An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;

A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;

And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency.

The power supply unit 100 includes a wind power generation module 110, a solar power generation module 120, a cogeneration module 130, and a commercial power module 140. And it can be constituted by varying the detailed composition ratio according to the situation and characteristics of the building. For example, in the city center, if the wind is blowing on the rooftop in winter or summer, the PV module may be more important if the wind power module is installed more heavily than the other modules or if the building is strong in sunlight. Since the high-rise building has its own power generation system such as cogeneration power generation system, the system can be constructed in such a way.

The power supply unit 100 supplies the power supplied from at least one of the wind power generation module 110, the solar power generation module 120, the cogeneration module 130 and the commercial power module 140 to the power control unit 200 or the roof And supplies it to the storage tank 300. The heat energy generated by the cogeneration module 130 is supplied to the hot water supply and heating unit 500.

More specifically, the cogeneration module 130 generates electricity by using gas or light oil (generally, gas) and transfers the generated heat energy to the steam heat exchanger 510 to generate steam, And transported to the rooftop storage tank 300 through the piping. The piping can be driven without any pump power, which is based on the high temperature steam buoyant force due to the density difference.

In addition, the cogeneration module 130 may be transferred to the hot water heat exchanger 520 by waste heat generated after the power generation to be used for hot water supply or heating.

The power control unit 200 includes a power frequency control module 210 and a power conversion module 220. The power control unit 200 converts the power supplied from the power supply unit 100 into a DC / And controls the inverter pump 400 to operate.

Generally, the inverter pump controls the speed by controlling the frequency in the DC power source. The operation efficiency at this time is related to the speed. In the present invention, since various regenerative power sources are supplied not only the commercial power source but also the constant speed, the operation efficiency is very high.

The roof storage tank 300 is constructed of an insulating structure for enhancing the energy storage efficiency and is capable of storing energy in the winter season, and supplies stored heat energy to the hot water in the summer season and hot water or heating in the winter season.

If the capacity of the rooftop storage tank 300 is saturated and can not be stored as position energy, it also has a function of storing energy by directly heating the stored water. Therefore, it is preferable that the rooftop storage tank 300 further includes a heating device for directly heating the water, and the energy source uses the energy generated by the wind power generator 110 and the solar power generator 120.

The hot water supply and heating unit 500 includes a steam heat exchanger 510, a hot water heat exchanger 520, a boiler 530, a hot water pipe and a heating pipe 540, (Waste heat) supplied from the steam heat exchanger 510 through the steam heat exchanger 510 and store the produced steam into the roof-top storage tank 300 without driving the pump through a separate steam pipe .

In addition, heat energy (waste heat) supplied from the cogeneration module 130 of the power supply unit 100 is supplied to the boiler through the hot water heat exchanger 520. The boiler heats the water supplied from the underground tank 600, To the hot water supply and heating pipe 540 having the valve structure.

The pumped-storage power generation unit 700 includes a pumped-storage power generation module 710 and an electricity distribution panel 720. The pumped-storage power generation unit 700 transmits the electricity generated by the pumped-storage power generation module 710 to the switchboard 720, ).

The control unit monitors the operation of the power supply unit 100 and at the same time controls the power supply control unit 200 to properly drive the inverter pump. At this time, the control unit 700 has various control methods for driving the inverter pump.

First, AC power is supplied from the cogeneration module 130 and the commercial power module 140 to perform AC / DC conversion to perform voltage control, DC / AC conversion after the AC / DC conversion, and power frequency control.

Second, DC power is supplied from the wind power generation module 110 and the solar power generation module 120, and DC / AC conversion is performed to perform power frequency control.

Third, AC power is supplied from at least one of the wind power generation module 110, the solar power generation module 120, the commercial power module 140, and the cogeneration module 130, and AC / After DC / AC conversion, power frequency control is performed again.

Fourth, AC power is supplied to the cogeneration module 130 and the commercial power module 140 to perform AC / DC conversion and voltage control is performed together with the DC power supplied from the wind power module 110 and the solar power module 120 And then DC / AC conversion to perform power frequency control.

The present invention differs from the prior art in that it is not focused on power generation but stores energy, and at the core is an inverter pump, which is supplied from commercial power, distributed power, solar power, wind power It is driven by electric power.

However, the present invention has the advantage of storing the energy from commercial power, wind power, solar power, and cogeneration with a structure for enhancing the energy storability and supplying the necessary energy at the required time have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible.

Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

100: power supply unit 110: wind power generation module
120: solar power generation module 130: cogeneration module
140: commercial power module 200: power control unit
210: Power frequency control module 220: Power conversion module
300: Rooftop storage tank 400: Inverter pump
500: Hot water supply and heating unit 510: Steam heat exchanger
520: hot water heat exchanger 530: boiler
540: Hot water piping and heating piping 600: Underground tank
700: Pumping unit 710: Pumping module
720: Switchboard 800:

Claims (24)

A power supply unit 100 for supplying thermal energy or electricity;
A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;
A roof storage tank 300 installed on the roof of the building for storing water;
An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;
A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;
An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;
A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;
And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency. Smart energy storage system and method using inverter pump driven by.
The method according to claim 1,
The power supply unit 100 includes at least one of a wind power generation module 110, a solar power generation module 120, a cogeneration module 130, and a commercial power module 140. Smart energy storage system and method using inverter pump driven by.
The method according to claim 1,
The power supply unit 100 supplies the power supplied from at least one of the wind power generation module 110, the solar power generation module 120, the cogeneration module 130 and the commercial power module 140 to the power control unit 200 or the roof And supplying the generated power to the storage tank (300).
The method according to claim 1,
The power supply unit 100 supplies the heat energy generated by the cogeneration module 130 to the hot water supply and heating unit 500. The smart energy storage system using the inverter pump driven by the renewable energy of the high- .
The method according to any one of claims 2 to 4,
The cogeneration power generation module 130 generates steam by transferring the generated energy (waste heat) to the steam heat exchanger 510. The smart energy storage system and the utilization method using the inverter pump driven by the renewed energy of the high- .
The method according to any one of claims 2 to 4,
The cogeneration module 130 transfers the generated energy (waste heat) to the hot water heat exchanger 520 so that it can be used for hot water supply or heating. A smart energy storage System and method of use.
The method according to claim 1,
A smart energy storage system and method using an inverter pump driven by renewable energy of a high-rise building, wherein the power control unit (200) comprises a power frequency control module (210) and a power conversion module (220).
The method according to claim 1,
The power control unit 200 performs DC / AC conversion of the power supplied from the power supply unit 100 to perform voltage control and then AC / DC conversion again to perform power frequency control and then drives the inverter pump. Smart energy storage system and method using inverter pump driven by.
The method according to claim 1,
Wherein the roof storage tank (300) is constructed of an insulating structure for enhancing the energy storage efficiency, and stores energy in the winter season, and a smart energy storage system and method using the inverter pump driven by the renewable energy of a high-rise building.
The method according to claim 1,
The rooftop storage tank (300) further includes a heating device for directly heating the water. The smart energy storage system and method using the inverter pump driven by renewable energy of a high-rise building.
11. The method of claim 10,
Wherein the heating device uses energy generated by the wind power generator (110) or the solar power generator (120), and a smart energy storage system and method using the inverter pump driven by renewable energy of a high-rise building.
The method according to claim 1,
The hot water supply and heating unit 500 is constituted by a steam heat exchanger 510, a hot water heat exchanger 520, a boiler 530, a hot water pipe and a heating pipe 540, Smart energy storage system and method using inverter pump.
The method according to claim 1,
The hot water supply and heating unit 500 generates steam through the steam heat exchanger 510 and supplies the generated steam to the steam generator 100 through a separate steam pipe And storing the energy in the roof-top storage tank (300) without driving. The smart energy storage system and the utilization method using the inverter pump driven by the renewable energy of the high-rise building.
The method according to claim 1,
The hot water supply and heating unit 500 supplies the thermal energy supplied from the cogeneration module 130 of the power supply unit 100 to the boiler through the hot water heat exchanger 520 and supplies the boiler to the underground tank 600 To the hot water piping and the heating pipe (540) having a three-way valve structure. The smart energy storage system and the utilization method using the inverter pump driven by the renewable energy of the high-rise building.
The method according to claim 1,
Wherein the pumped-storage power generation unit (700) comprises a pumped storage power generation module (710) and an electric distribution panel (720).
The method according to claim 1,
The pumped-storage power generation unit 700 drives the electricity generated by the pumped-storage power generation module 710 to the switchboard 720 and stores the water used for power generation in the underground tank 600. Smart energy storage system and method using inverter pump.
The method according to claim 1,
The control unit 700 receives AC power from the cogeneration power generation module 130 or the commercial power supply module 140, performs AC / DC conversion to perform voltage control, and performs DC / Smart energy storage system and method using inverter pump driven by renewable energy in buildings.
The method according to claim 1,
The control unit 700 receives DC power from the wind power generation module 110 or the solar power generation module 120 and performs DC / AC conversion to perform power frequency control. The inverter pump drives the renewed energy of the high- Smart energy storage systems used and methods of use.
The method according to claim 1,
The control unit 700 receives AC power from at least one of the wind power generation module 110, the solar power generation module 120, the commercial power supply module 140 and the cogeneration module 130 and AC / And a power frequency control is performed after DC / AC conversion, and a smart energy storage system and a utilization method using an inverter pump driven by renewable energy of a high-rise building.
The method according to claim 1,
The control unit 700 receives the AC power from the cogeneration power generation module 130 or the commercial power supply module 140 and converts the AC power to DC power and supplies the AC power to the wind power generation module 110 or the solar power generation module 120, And a power frequency control is performed after DC / AC conversion of the DC / AC voltage is performed. The smart energy storage system and the utilization method using the inverter pump driven by renewable energy of a high-rise building.
A power supply unit 100 for supplying thermal energy or electricity;
A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;
A roof storage tank 300 installed on the roof of the building for storing water;
An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;
A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;
An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;
A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;
And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency,
A smart energy storage system and an inverter pump using an inverter pump driven by renewable energy of a high-rise building, characterized in that the inverter pump (400) is driven in accordance with power supplied from at least one of commercial power, distributed power, sunlight and wind power Way.
A power supply unit 100 for supplying thermal energy or electricity;
A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;
A roof storage tank 300 installed on the roof of the building for storing water;
An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;
A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;
An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;
A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;
And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency,
A smart energy storage system and method using an inverter pump driven by renewable energy of a high-rise building, characterized in that energy is stored using at least one of commercial power, wind power generation, solar power generation and cogeneration power generation.
A power supply unit 100 for supplying thermal energy or electricity;
A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;
A roof storage tank 300 installed on the roof of the building for storing water;
An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;
A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;
An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;
A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;
And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency,
A smart energy storage system and method using an inverter pump driven by renewable energy of a high-rise building, characterized in that thermal energy stored in the roof storage tank (300) is supplied as hot water to the summer during hot season and hot water or heating is supplied in the winter season.
A power supply unit 100 for supplying thermal energy or electricity;
A power control unit 200 for driving the inverter pump 400 by voltage control and frequency conversion of the supplied electricity;
A roof storage tank 300 installed on the roof of the building for storing water;
An inverter pump 400 driven by the power supplied from the power control unit 200 to pump the water in the underground tank and store it in the roof storage tank 300;
A hot water supply and heating unit 500 for supplying hot water or heating to the building by receiving thermal energy from the power supply unit 100;
An underground tank 600 located in the basement of the building for supplying water to the roof storage tank 300 and the hot water supply / heating unit 500;
A pumped water generating portion 700 for dropping water from the rooftop storage tank 300 to generate pumped water;
And a control unit 800 for controlling the power supply unit 100, the power supply control unit 200, the hot water supply / heating unit 500, and the pumped water generation unit 700 to increase energy storage efficiency,
A smart energy storage system using an inverter pump driven by renewable energy of a high-rise building, characterized in that energy is stored by directly heating the stored water when the capacity of the roof storage tank (300) is saturated and can not be stored as potential energy. How to use.

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