KR20080088063A - Heating system using aerogenerator - Google Patents

Abstract

A heating system using a wind power generator is provided to store excess electricity for later use or sell the excess electricity for commercial purpose after using electricity for filling existing demand. A heating system using a wind power generator includes a wind power generator(50), an inverter(60), a heater(70), a temperature sensor(80), a condenser(90), and a controller(100). The power generator rotates a rotator by using wind to generate power. The converter converts DC power generated from the wind power generator into AC power having a predetermined frequency. The heater is installed in a heat storage tank(40). The heater heats heat medium stored in the heat storage tank. The temperature sensor detects the temperature of the heat medium. The condenser is connected to the heater by using a switch(110). The controller detects amount of current supplied from the converter and amount of current consumed in the heater, and receives a signal of the temperature sensor to control the whole operation of the converter, a heating source, a heater, and a switch.

Description

Heating system using a wind power generator {Heating system using aerogenerator}

1 is a configuration diagram of a heating system using a wind turbine according to an embodiment of the present invention,

2 is a control flowchart of a heating system using a wind turbine according to an embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: heat source means 20: pump

30: heat dissipation part 40: heat storage tank

50: wind generator 60: inverter

70: heater 80: temperature sensor

90: capacitor 100: control unit

110: switch 120: phase controller

The present invention relates to a heating system using a wind power generator, and more particularly, by using the power generated from the wind power generator as an auxiliary heat source means for heating and accumulating the heat medium by connecting the existing heating device to the heat source consumption of the existing heating device. The present invention relates to a heating system using a wind power generator that can minimize heating costs by minimizing heating costs.

In general, heating devices used to supply heating and hot water in places where heating is required, such as homes, can be divided into oil boilers, gas boilers, and electric boilers, depending on the fuel used. In relation to the use, there is a problem of increasing the heating cost burden on the consumer in case of unexpected surge of oil price and natural gas price due to international situation.

In addition, in the case of electric boilers, the heaters are heated by using a low-cost late-night electricity to heat the heat medium to heat and accumulate it. After that, there was a limit to keeping the heat medium at a high temperature.

In order to make up for these shortcomings and save energy, recently, so-called 'grid-connected photovoltaic power generation systems', which use electricity and solar heat in combination, have been provided.In addition, solar energy has low energy density and changes seasonally and hourly. In other words, due to its short sunshine time and poor coping with winter climates such as cold weather and cold weather, its heat collection efficiency is lower than that of solar collectors. There was a problem.

On the other hand, the wind power generator is a type of generator that generates electric power by converting kinetic energy of the flow of wind energy into electric energy by a blade, and has no impact on the environment and no pollution source. I am in the spotlight.

With this in mind, the present inventors have earnestly studied to develop a breakthrough heating apparatus that can naturally solve the structural problems of the conventional heating apparatus, and as a result, the present invention has been devised.

Therefore, an object of the present invention is to provide a heating system using a wind power generator to maximize the energy efficiency of heating and heat storage of heat medium for heating or hot water supply by connecting the power generated from the wind power generator to the existing heating device. It is.

Another object of the present invention is to provide a heating system using a wind power generator to be produced from the wind power generator and supplied to the load and to store the surplus power remaining or supply to the grid power supply.

In order to achieve the above object, the present invention provides a heating system including a pump for forcibly circulating a heat medium heated by a heat source means such as a boiler to the heat dissipation unit, and a heat storage tank for accumulating the heat medium for heating and hot water supply. A wind power generator for generating electric power while the rotor is rotated by wind; An inverter for converting DC power generated from the wind generator into AC power of a predetermined frequency; A heater installed inside the heat storage tank and heating the heat medium filled in the heat storage tank with power supplied through the inverter; A temperature sensor installed in the heat storage tank and sensing a temperature of the heat medium; A capacitor charged with power supplied through the inverter and connected through the heater and a switch; And a control unit which detects the amount of current supplied to the inverter and the amount of current consumed by the heater and receives a signal from a temperature sensor to control the operation of the inverter, the heat source means, and the heater and the switch. to provide.

Hereinafter, the configuration according to each embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Prior to this, terms to be described below are defined in consideration of functions in the present invention, and it should be understood that they should be interpreted as concepts and inherent commonly used meanings consistent with the technical spirit of the present invention.

In addition, when it is determined that the detailed description of known functions or configurations related to the present invention may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a configuration diagram of a heating system using a wind power generator according to an embodiment of the present invention, as shown in the present invention, the heat source means 10, the pump 20, the heat dissipation unit 30, the heat storage tank 40 , Wind generator 50, inverter 60, heater 70, temperature sensor 80, capacitor 90, the control unit 100 and the ancestor 130 is made of roughly.

First, the heat source means 10 is a conventional heating device for heating the heat medium for heating, in the present invention, the heat generated by the resistance of the oil boiler using petroleum as fuel or the gas boiler using gas or fuel It is commonly referred to as heating or hot water supply by heating a heating medium such as an electric boiler.

The heat source means 10 is equipped with a drive detection unit 120 for detecting the drive and sending a signal to the control unit 100.

The pump 20 is installed between the heat source means 10 and the heat dissipation part 30, and the operation such as forcibly circulating the heat medium heated by the heat source means 10 according to the control signal of the controller 100 and the flow of the heat medium. Serves to control.

The heat dissipation unit 30 is installed between the pump 20 and the heat storage tank 40 to discharge the heat received from the heat medium continuously circulated by the pump 20 to perform a heating function.

The heat storage tank 40 stores the heat medium heated by the heat source means 10 and the heater 70, and on the outside thereof, the high temperature heat medium cools due to contact with external air while preventing the thermal efficiency from decreasing. A heat insulating layer (not shown) is provided, and a check valve (not shown) for replenishing the consumption according to the natural evaporation of the heat medium and a drain valve (not shown) for facilitating exchange of the heat medium are provided.

The heat storage tank 40 is provided to be used in combination with the existing heating device that is already installed in a place requiring heating, such as each home by a separate production.

The wind power generator 50 is installed on a rooftop of a building or a place where wind is frequently used to obtain electric energy by turning a generator into natural wind, and the generated power is generally controlled by the controller 100.

Since the wind generator 50 needs to rotate at a constant speed irrespective of the wind speed, it is preferable that the control unit 100 simultaneously perform a control such as changing the inclination of the rotor according to the wind speed.

Inverter 60 is connected to the control unit 100 serves to convert the DC power generated from the wind turbine 50 into AC power of a predetermined frequency.

The power converted by the inverter 60 is used as a heat source for heating the heater 70 under the control of the controller 100.

And when the heating is not required from the wind turbine 50 is sent to the capacitor 90 and stored.

The heater 70 is installed inside the heat storage tank 40 to heat the heat medium, and is electrically connected to the AC power supplied through the inverter 60.

The heater 70 may prevent overheating because the supply of power is automatically cut off when the control unit 100 receives the abnormal signal from the temperature sensor 80.

Temperature sensor 80 is installed inside the heat storage tank 40 detects the temperature of the heat medium and serves to transmit the signal to the control unit 100.

That is, the temperature sensor 80 senses the heating temperature of the heat medium and sends a signal to the control unit 100 so that the heating and hot water temperature can be approached to a temperature selected by the user, and at the same time, the heat medium and the heater in the heat storage tank 40. The 70 is prevented from overheating.

The capacitor 90 charges surplus power of the wind power generator 50 supplied through the inverter 60. When the power supply is stopped from the wind power generator 50 when the heating system is operated, the control signal of the controller 100 is stopped. As a function of heating the heater 70. That is, the heater 70 and the switch 110 are connected to supply power to the heater 70 according to the on / off operation of the switch 110.

Such a capacitor 90 has intermediate characteristics between a conventional capacitor having a low energy density characteristic and a secondary battery having a low power density characteristic, and has characteristics such as rapid charging / discharging, high charging / discharging efficiency, and semi-permanent lifetime high output. It is preferable to use a supercapacitor.

The control unit 100 is to control the heating system according to the invention as a whole, the pump 20, the inverter 60, the heater 70, the temperature sensor 80, the capacitor 90, the switch 110 and sphere The copper sensing unit 120 is electrically connected to each other, and receives a signal from the temperature sensor 80 and the driving sensing unit 120 to perform a corresponding control function.

The ancestor 130 plays a role of transmitting surplus power of the wind power generator 50 determined by the controller 100 to the grid power supply side.

Since the surplus power can be sold back to the system power source such as an electric power market through the ancestor 130, the electric charge can be reduced by the power generated by the power generation of the wind power generator 50.

Referring to Figure 2 describes the operating state of the heating system using a wind power generator according to an embodiment of the present invention configured as described above.

First, when a power signal for driving a heating system is applied by a user, the controller 100 detects a heating or hot water set temperature corresponding to a temperature required by the user, and stores the heat storage tank 40 through the temperature sensor 80. The temperature of the heat medium inside is detected.

If the temperature of the heat medium in the step S10 is lower than the user set temperature, it is determined whether the power supplied from the wind power generator 50 exists.

At this time, if the temperature of the heat medium is higher than or equal to the user set temperature in step S10 is returned.

As a result of the determination in step S20, when power is supplied from the wind turbine 50, the heater 70 is heated and the pump 20 is driven. (S30) The heated heating medium is rotated by the pump 20. Forced circulation

In step S30, it is determined whether the heat medium has reached the user's set temperature.

As a result of the determination in step S40, if the temperature of the heat medium reaches the user's set temperature, the heating of the heater 70 is stopped.

At this time, if the determination result in step S40, if the temperature of the heat medium did not reach the user set temperature, the process returns to step S30.

On the other hand, as a result of the determination in step S20, when power is not supplied from the wind turbine 50, it is determined whether there is a current stored in the capacitor 90 (S60).

As a result of the determination in step S60, if there is a current stored in the capacitor 90, the switch 110 is turned on to heat the heater 70 and drive the pump 20. (S70, S80) The heating medium thus heated. Is forcedly circulated by the rotation of the pump 20.

In step S80, it is determined whether the heating medium has reached the user's set temperature.

As a result of the determination in step S90, when the temperature of the heat medium reaches a user set temperature, the switch 110 is turned off to stop heating of the heater 70. (S100)

At this time, if the determination result in step S90, if the temperature of the heat medium did not reach the user set temperature, the process returns to step S80.

On the other hand, as a result of the determination in step S60, when there is no current stored in the capacitor, the corresponding heat source means is driven. (S110) Accordingly, the heat source means heats the heating medium while burning the corresponding fuel, and the heated heating medium is pump 20 Forced circulation by the rotation of) performs heating.

In step S110, it is determined whether the heating medium has reached the user's set temperature.

As a result of the determination in step S120, if the temperature of the heat medium reaches the user's set temperature, the driving of the heat source means is stopped.

At this time, as a result of the determination in step S120, if the temperature of the heat medium does not reach the user set temperature, the process returns to step S110.

By repeating such an operation sequence, the heating can be performed while minimizing the consumption of fuel for driving the heat source means.

On the other hand, the present invention is not limited to the above-described embodiment and the accompanying drawings, it can be changed to other embodiments equivalent to substitutions and equivalents within the scope without departing from the technical spirit of the present invention. It will be apparent to those of ordinary skill in the art.

The present invention configured as described above is able to heat and heat storage the heat medium by connecting the power produced from the wind generator to the existing heating device. Therefore, since the consumption rate of the existing energy due to the heating and hot water supply of the heating device is minimized, the heating cost can be greatly reduced and the efficiency of heating can be improved.

In addition, the present invention is to be produced from the wind power generator to be supplied to the load and the remaining surplus power can be stored or supplied to the grid power supply side. Therefore, the power can be sold to the grid power source such as the electric power market, so it is possible to reduce the electricity bill as much as the power generated by the power generation of the wind power generator and to generate profit through the commercialization of electricity.

Claims (2)

A heating system comprising a pump for forcibly circulating a heat medium heated by a heat source means such as a boiler to a heat dissipation unit, and a heat storage tank for accumulating the heat medium for heating and hot water supply. A wind power generator for generating electric power while the rotor is rotated by wind; An inverter for converting the DC power generated from the wind generator into AC power of a predetermined frequency; A heater installed inside the heat storage tank and heating the heat medium filled in the heat storage tank with power supplied through the inverter; A temperature sensor installed in the heat storage tank and sensing a temperature of the heat medium; A capacitor charged with power supplied through the inverter and connected through the heater and a switch; And A control unit which detects the amount of current supplied to the inverter and the amount of current consumed by the heater and receives a signal from a temperature sensor to control overall operation of the inverter, the heat source means, the heater, and the switch; Heating system using a wind turbine comprising a. The method of claim 1, The surplus power of the wind power generator determined by the control unit further comprises an ancestor for transmitting power to the grid power supply side.

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