KR101445266B1 - Central Control Association Management System of New Renewable Energy for Air Conditioning and Heating - Google Patents

Abstract

The present invention relates to a new and renewable energy central control interlocking management system for cooling and heating which effectively utilizes renewable energy without waste by organically controlling facilities such as solar power generation, wind power generation, solar heat, heat pump (air heat source and geothermal heat) will be.

Description

{Central Control Association Management System of New Renewable Energy for Air Conditioning}

The present invention relates to a new and renewable energy centralized control interlocking management system for heating and cooling, and more particularly, to a system and method for efficiently controlling renewable energy without wastage by organically controlling facilities such as solar power generation, wind power generation, solar heat, and heat pump (air heat source and geothermal heat) The present invention relates to a control system for centralized control of renewable energy for cooling and heating utilizing energy.

The importance of a system capable of cooling and heating without fossil fuels due to the problem of depletion of fossil fuels worldwide and the natural destruction caused by the carbon dioxide emissions that cause environmental problems, as well as the instability of oil prices and the regulation response of the climate change convention . New and renewable energy, which is generally recognized as a future energy source, includes solar, solar, wind, geothermal, and heat pumps (air heat sources, geothermal heat).

These various renewable energies are different from each other in terms of energy conversion characteristics, and each independent system is applied to produce electric power separately, and the conditions necessary for energy conversion for solar, solar, wind, geothermal, Failure to do so would not only make energy conversion impossible in each installation, but could also result in waste due to overproduction.

If a single system of wind power, heat pump (air heat source and geothermal), solar power generation, and solar heat system is supplied as one system, it is applied as an independent system without central control system which can control the whole system in a lump, Energy is overproduced, and because it can not supply the energy produced immediately to other facilities requiring one energy source, it is necessary to use renewable energy facilities and additional energy sources such as commercial power. There is a problem.

For example, as shown in Korean Patent Registration No. 10-0903765, even in a cooling / heating system using existing solar heaters, organic interlocking between a solar heating facility and a heat pump can not be performed, the heat pump may not operate in cold weather, In addition, it is not a way to reduce electricity cost burden by surplus electric power by linking generation electric power to system using only solar heat.

It is therefore an object of the present invention to provide a control module and a heat pump which are capable of operating a control module and a heat pump that require electric energy using electric power using solar power generation and wind power generation, The heat of the storage tank is heated by the fluid (water or other liquid) in the winter season. The heat pump is operated to assist the heating when necessary. In the summer, the cooling water is cooled by the heat pump (air heat source and geothermal) (Such as water and other liquids) in a heat storage tank that has been stored through a solar facility even during cold weather in the winter season, by supplying hot air to the heat pump machine room, thereby enabling the heat pump to operate effectively without stopping To provide a centralized control and management system for new and renewable energy for heating and cooling.

In addition, a new and renewable energy central control interlocking management system for air-conditioning and heating that can reduce electricity costs by supplying power to the power system by operating control modules and heat pumps that require electric energy from solar power generation and wind power generation .

First, a summary of the features of the present invention will be described. In accordance with an aspect of the present invention, a centralized control and management system for renewable energy for cooling and heating includes a solar power generation system; Wind power system; A solar control module, a monitoring and control module, and a heat pump, which are operated by the production power of the solar power generation system or the wind power generation system; A heat storage tank including a first heat exchanger and a second heat exchanger in fluid; A hot water tank including a third heat exchanger in the fluid; A solar collector connected to both ends of the second heat exchanger by piping; A first circulation pump installed in the middle of an input pipe of a pipe connecting the second heat exchanger and the solar collector; A heating pipe connected to both ends of the first heat exchanger; A cooling pipe connected to both ends of the third heat exchanger; A heating heat pump pipe connected to two holes of the heat storage tank; A cooling heat pump piping connected to two holes of the compression tank; And a heat pump machine room including the heat pump and the fan coil, wherein input pipes of the heating heat pump pipe and the cooling heat pump pipe are connected to an input pipe of the heat pump via a second circulation pump, The heat pump piping and the output pipes of the cooling heat pump pipe are connected to two output ports of a three-way valve connected to an output pipe of the heat pump, pipes connected to the other two holes of the heat storage tank are connected to both ends of the fan coil, Wherein the solar control module controls the operation of the first circulation pump and the monitoring and control module controls the operation of the heat pump, The second circulation pump, and the third circulation pump.

Wherein the heat pump is operated in the winter season by using the fluid flowing through the heating pipe heated by the solar collector so that the fluid flowing through the heating heat pump pipe is heated by the operation of the heat pump to assist the heating of the winter season, And a second circulation pump for circulating the fluid in the heat storage tank to the fan coil through the operation of the third circulation pump to cool hot air in the heat pump machine room, It is possible to prevent the operation stop of the heat pump during the winter season by supplying the wind.

Wherein the solar control module controls operation of the first circulation pump according to a signal of at least one temperature sensor installed in the storage tank and the monitoring and control module includes at least one temperature sensor installed in the storage tank and the hot- The operation of the second circulation pump can be controlled according to the signal.

The monitoring and control module may be configured to monitor at least one of temperature states according to signals of at least one temperature sensor provided in the heat storage tank and the hot water storage tank and a signal of at least one temperature sensor installed in a pipe connecting the second heat exchanger and the solar heat collector A temperature state according to a signal of a temperature sensor provided around the second circulation pump in the heating heat pump piping or a flow rate state according to a signal of a flow sensor fixed between the output pipe of the heat pump and the three- And display means for monitoring the display.

And a valve controller mounted between the three-way valve and the flow rate sensor, wherein the monitoring and control module controls the flow rate to the three-way valve by adjusting the valve controller according to the flow rate state.

Wherein the monitoring and control module monitors production power of the solar power generation system and the wind power generation system and controls the power generation of the solar power generation system when the production power is less than the power consumption of the solar control module, Power may be supplied from the power system.

Wherein the monitoring and control module calculates a surplus power to supply the solar control module, the monitoring and control module, and the heat pump with the power to be consumed and maintain the surplus power in the external power system So that the amount of power used can be subtracted from the watt-hour meter by the corresponding amount of power.

According to the present invention, it is possible to operate a control module and a heat pump, which require electric energy by using electric power using photovoltaic power generation and wind power generation, (Water and other liquids) to heat the winter season. The heat pump operates the heat pump to assist the heating when necessary. In the summer, it can be cooled by cold fluid (water or other liquid) in the cooling tank by heat pump (air heat source and geothermal heat) (Hot water, other liquids, etc.) stored in a heat storage tank that has been stored through a solar facility in the cold season can be supplied to the heat pump machine room by supplying hot air to the fan coil so that the heat pump can be effectively operated without stopping the operation at all times .

In addition, electric power can be saved by operating the control module and heat pump, which require electric energy from solar power generation and wind power generation, and supplying the remaining power in connection with the power system.

FIG. 1 is a view for explaining a centralized control interlocking management system for renewable energy for cooling and heating according to an embodiment of the present invention.
FIG. 2 is a view for explaining the operation concept of a renewable energy central control interlocking management system for cooling and heating according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

FIG. 1 is a view for explaining a system 100 for managing centralized control of renewable energy for cooling and heating according to an embodiment of the present invention.

Referring to FIG. 1, a system 100 for managing centralized control of renewable energy for cooling and heating according to an embodiment of the present invention includes a solar power generation system 110, a solar collector 120, a solar control module 121, A heat pump machine room 170 including a heat pump 171 and a fan coil 172, a circulation pump 160 for circulating the hot water in the circulation tank 170, a wind power generation system 130, a heat storage tank 140, a heat storage tank 150, a monitoring and control module 160, Pumps 124, 173, 177, and 181, fan coils 180 for cooling and heating, and the like. And further includes various temperature sensors 122, 123, 161, 162, 163, 164 and 167, three-way valves 174 and 182, a valve controller 175, an ultrasonic flow rate sensor 176, and the like.

The photovoltaic power generation system 110 can generate electricity using solar cells that convert solar energy into electrical energy.

The wind power generation system 120 can generate electric power using a module that converts rotational force by wind power into electric energy.

The heat pump 171 is a device for cooling the surroundings by releasing heat or absorbing heat by using condensation and expansion of the refrigerant by using the heat of the air or the geothermal heat and entering the heat pump 171 into the inlet pipe 173 The fluid (water or other liquid) can be heated or cooled and discharged to the output tube 176.

The solar control module 121, the monitoring and control module 160 and the heat pump 172 are operated by the power generated by the solar power generation system 110 or the wind power generation system 120, The monitoring and control module 160 can control the operation of the circulation pump 124 in accordance with the signals of the temperature sensors 122 and 123 installed at the upper and lower portions of the heat storage tank 140, Temperature sensors 161 and 162 installed at the upper and lower parts of the tank 140 and installed at the upper and lower parts of the supercooling tank 150 for detecting the temperature and the temperature sensors 165 and 166 The operation of the second circulation pump 173 can be controlled.

In addition, the monitoring and control module 160 may perform overall control and monitoring of the central control interlocking management system 100 and display the same on a predetermined display device. The monitoring and control module 160 may monitor the production power of the solar power generation system 110 and the wind power generation system 120 and the production power may be supplied to the solar control module 121, The solar control module 121, the monitoring and control module 160, and the heat pump 171 by receiving power from the external power system when the power consumption of the heat pump 171 is lower than the power consumption of the heat pump 171.

The monitoring and control module 160 monitors the power consumption of the solar control module 121, the monitoring and control module 160, and the heat pump 171 with the production power of the solar power generation system 110 and the wind power generation system 120 And supplies the surplus power to the external power system connected to the predetermined watt-hour meter, so that the watt-hour meter subtracts the used power amount by the watt-hour power. In this way, the surplus electric power can be supplied in connection with the electric power system to reduce the electricity bill.

The heat storage tank 140 is filled with a fluid (hereinafter referred to as water or other liquid that can be circulated) and includes a first heat exchanger 145 and a second heat exchanger 146 therein. The hot-water storage tank 150 is filled with a fluid (hereinafter referred to as water or other liquid that can be circulated) and includes a third heat exchanger 155 therein. The heat exchangers 145, 146, and 155 form a pipe (pipe or the like) in the form of a coil, and are devices for facilitating heat transfer with the fluid in the tank.

The solar collector 120 collects solar heat and heats a fluid (hereinafter, referred to as circulating water or other liquid) flowing in the inner tube. The input tube and the output tube are connected to both ends of the second heat exchanger 146 And is connected to the pipe 122. The first circulation pump 124 may be installed in the middle of the input pipe (the pipe connected to the input tube of the solar collector) of the pipe connecting the second heat exchanger 146 and the solar collector 120. The fluid circulated in the solar heat collector 120 flows through the pipe 126 by the operation of the first circulation pump 124 to heat the fluid in the heat storage tank 140 in the second heat exchanger 146.

A heating pipe 141 through which fluid (hereinafter referred to as circulating water or other liquid) flows can be connected to both ends of the first heat exchanger 145. A fluid (Hereinafter referred to as " circulating water " or " other liquid "). The heating heat pump pipe 142 is connected to the two holes of the heat storage tank 140 and the cooling heat pump pipe 151 is connected to the two holes of the water cooling tank 150 so that the fluid Which means water or other liquid) can flow to the heat pump 171.

The solar control module 121 controls the operation of the circulation pump 181 by checking the collecting temperature sensor 125 and the upper and lower temperature sensors 122 and 123 of the regenerating tank 140, The heated fluid flowing through the second heat exchanger 146 by the same solar collector 120 and the circulating pump 181 heats the fluid in the heat storage tank 140 and the circulating pump 181 and the fan coil 180 (By manual or electrical control) by setting the flow path of the three-way valve 182 to block the fluid circulation to the cooling pipeline 152 so that the heated fluid flows through the heating pipeline 141, Lt; / RTI > The heating duct 141 can be used as a floor duct or the hot water can be supplied through the heating duct 141 and hot air from the coil pipe 180 of the fan coil 180 can be heated during the winter season. The heat pump 171 and the three-way valve 174 are set and operated (manual or electrical The heating of the fluid in the heat storage tank 140 can be assisted by heating the fluid flowing through the heating heat pump pipe 142 to heat the fluid in the heat storage tank 140.

The solar control module 121 checks the upper and lower temperature sensors 122 and 123 of the accumulation tank temperature sensor 125 and the accumulation tank 140 to control the operation of the circulation pump 181, The temperature difference between the upper and lower temperature sensors 122 and 123 of the heat accumulation tank 140 may be different from the temperature difference between the upper and lower temperature sensors 122 and 123. For example, It is possible to heat the fluid in the heat storage tank 140 by operating the circulation pump 181 when the temperature of the heat storage tank 140 is equal to or more than a certain level (e.g., 5 degrees or more). Most of the monitoring, setting, and control necessary for the operation of the central control interlocking management system 100, such as the heat pump 171, the circulation pumps 173, 177, 181, the valve controller 175, ). ≪ / RTI >

In the summer, the operation of the solar collector 120 and the circulation pump 181 is stopped and the circulation pump 181 and the fan coil 180 are operated to set the flow path of the three-way valve 182 ) By preventing the fluid circulation to the heating duct 141, the cold fluid flows through the cooling duct 152, so that cooling can be performed in the summer. The cold air from the coiled pipe of the fan coil 180 can be cooled during the summer season. At this time, the second circulation pump 173, the heat pump 171 and the three-way valve 174 are set and operated (manually or electrically) to cool the fluid flowing through the cooling heat pump pipe 151, 150) is cooled to enable cooling in summer.

The heating heat pump pipe 142 is connected to the two holes of the heat storage tank 140 and the cooling heat pump pipe 151 is connected to the two holes of the water cooling tank 150 so that the fluid The heat pump piping 142 and the input piping of the cooling heat pump piping 151 are connected in common and the second circulation pump 173 is connected in common so that the heat pump 171 can flow to the heat pump 171. [ The output port of the second circulation pump 173 is connected to the input pipe of the heat pump 171 and the output pipes of the heating heat pump pipe 142 and the cooling heat pump pipe 151 are connected to the heat pump 171 Way valve 174 connected to the output tube of the engine. The temperature sensor 167, the valve controller 175 and the ultrasonic flow sensor 176 are not necessarily required and may be added for monitoring and control in the monitoring and control module 160 as follows.

The piping 143 connected to the other two holes of the heat storage tank 140 is connected to both ends of the fan coil 172 which is a coil type pipe and is connected to both ends of the fan coil 172 in the middle of the input pipe And a third circulation pump 177 are included. In particular, during the winter season, the third circulation pump 177 operates to supply the heat of the heat storage tank 140 to the fan coil 172, thereby supplying warm air to the heat pump machine room 170, It is possible to prevent the operation stop of the motor 171.

As described above, in the renewable energy central control interlocking management system 100 for cooling and heating according to the present invention, it is possible to perform heating in the winter season by using the fluid flowing through the heating ducts 141 heated by the solar heat collector 120, The fluid flowing through the heating heat pump pipe 142 can be heated by the operation of the pump 171 to assist in heating the winter season. During the summer season, the heat pump 171 is operated to cool the fluid flowing through the cooling heat pipe 151, so that cooling can be performed using the fluid flowing through the cooling pipe 152.

In addition, the monitoring and control module 160 may include a display device, such as an LCD, for monitoring the overall control status of the central control interlocking management system 100. For example, the monitoring and control module 160 may include one or more temperature sensors (e.g., 161 in the upper portion, 162 in the lower portion) installed in the accumulation tank 140, one or more temperature sensors (e.g., The upper temperature 165, and the lower temperature 166) can be displayed on the display device.

The monitoring and control module 160 may also include one or more temperature sensors (e.g., input piping 164, output piping 163) installed in the piping 126 connecting the second heat exchanger 146 and the solar collector 120, And the temperature state according to the electrical signal of the temperature sensor 167 installed around the second circulation pump 146 of the heating heat pump pipe 142 can be displayed on the display device, And the flow rate state according to the electrical signal of the ultrasonic flow rate sensor 176 fixed between the output pipe of the heat pump 171 and the three-way valve 174 can be displayed on the display device. It is possible to appropriately control the purifying pumps 173 and 181, the heat pump 171, the fan coils 180 and 172, the three-way valves 182 and 174 and the like in accordance with the temperature and the flow rate state.

The valve controller 175 may be mounted between the three-way valve 174 and the ultrasonic flow rate sensor 176 and the monitoring and control module 160 may be controlled by the ultrasonic flow rate sensor 176, The valve controller 175 may be controlled to appropriately control the flow rate of the three-way valve 174 to a constant flow rate.

2, the control modules 121 and 160, which require electric energy using electric power using solar power generation and wind power generation, And the heat pump 171 is operated to heat the room by the fluid (water or other liquid) of the warmed storage tank 140 heated by the solar collector 120 using the solar heat collector 120, (Water or other liquid) of the hot-water storage tank 150 by the heat pump 171 during the summer season and the heat storage tank 140 which is stored through the solar heat collector 120 during the cold season, (Such as water or other liquid) of the heat pump 171 to the fan coil 172 to supply hot air to the heat pump machine room 170, thereby enabling the heat pump 171 to operate effectively without stopping the operation at all times.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

Photovoltaic systems (110)
The solar collector (120)
The solar control module (121)
Wind Power Systems (130)
The heat storage tank 140,
The heat storage tank (150)
Monitoring and control module (160)
Heat pump (171)
The fan coil 172,
Heat pump machine room (170)
The circulation pumps 124, 173, 177, 181,
Fan coils for cooling and heating (180)
The temperature sensors 122, 123, 161, 162, 163, 164, 167,
Three-way valves 174, 182,
Valve controller 175,
Ultrasonic flow meters (176)

Claims (7)

PV system; Wind power system; A solar control module, a monitoring and control module, and a heat pump, which are operated by the production power of the solar power generation system or the wind power generation system;
A heat storage tank including a first heat exchanger and a second heat exchanger in fluid; A hot water tank including a third heat exchanger in the fluid; A solar collector connected to both ends of the second heat exchanger by piping; A first circulation pump installed in the middle of an input pipe of a pipe connecting the second heat exchanger and the solar collector;
A heating pipe connected to both ends of the first heat exchanger; A cooling pipe connected to both ends of the third heat exchanger; A heating heat pump pipe connected to two holes of the heat storage tank; A cooling heat pump piping connected to two holes of the compression tank; And a heat pump machine chamber including the heat pump and the fan coil,
The heat pump pipe and the cooling heat pump pipe are connected to the input pipe of the heat pump via a second circulation pump and the output pipes of the heating heat pump pipe and the cooling heat pump pipe are connected to the heat pump Connected to two output ports of a three-way valve connected to the output tube,
And a third circulation pump in the middle of the input pipe among the pipes connected to both ends of the fan coil, wherein the pipe connected to the other two holes of the heat storage tank is connected to both ends of the fan coil,
Wherein the solar control module controls operation of the first circulation pump and the monitoring and control module controls operation of the heat pump, the second circulation pump, and the third circulation pump. Renewable Energy Central Control Interlocking Management System. The method according to claim 1,
And a heater for heating the fluid flowing through the heating heat pump pipe by the operation of the heat pump to assist the heating of the winter season by using the fluid flowing through the heating duct heated by the solar collector,
In the summer, the heat pump cools the fluid flowing through the cooling heat pump pipe by the operation of the heat pump and uses the fluid flowing through the cooling pipe to cool down during the summer,
Wherein the first circulation pump and the second circulation pump are connected to each other through a heat exchanger, and the third circulation pump is operated to flow the fluid in the heat storage tank to the fan coil to supply hot air to the heat pump machine room, Central Control Interlocking Management System. The method according to claim 1,
The solar control module controls the operation of the first circulation pump according to a signal of at least one temperature sensor installed in the heat storage tank,
Wherein the monitoring and control module controls the operation of the second circulation pump in accordance with a signal from at least one temperature sensor installed in the heat storage tank and the hot-water storage tank, respectively. The method according to claim 1,
The monitoring and control module comprises:
A temperature state according to a signal of at least one temperature sensor provided respectively in the heat storage tank and the water storage tank,
A temperature sensor for detecting temperature of each of the at least one temperature sensor installed in the pipe connecting the second heat exchanger and the solar collector,
A temperature state according to a signal of a temperature sensor provided around the second circulation pump in the heating heat pump piping, or
A flow rate state according to a signal of a flow rate sensor fixed between an output tube of the heat pump and the three-
And a display unit for monitoring the temperature of the cooling water. 5. The method of claim 4,
And a valve controller mounted between the three-way valve and the flow rate sensor,
Wherein the monitoring and control module controls the flow rate to the three-way valve by adjusting the valve controller according to the flow rate state. The method according to claim 1,
Wherein the monitoring and control module monitors production power of the solar power generation system and the wind power generation system,
Wherein power is supplied from an external power system when the generated power is less than the power consumption of the solar control module, the monitoring and control module, and the heat pump. The method according to claim 6,
Wherein the monitoring and control module calculates a surplus power to supply the solar control module, the monitoring and control module, and the heat pump with the power to be consumed and maintain the surplus power in the external power system And the amount of power consumed by the watt hour meter is subtracted from the watt hour meter by the corresponding amount of electric power.

Images