KR20220099289A - Greenhouse energy supply method using convergence energy production and storage technology - Google Patents

Abstract

The present invention relates to a greenhouse energy supply system and method using convergence energy production and storage technology, and more specifically, to greenhouse energy supply system using convergence energy production and storage technology, which comprises: multiple heat source energy production sources producing energy and supplying a heat source; an underground heat distributor buried in the ground on a greenhouse side and storing a heat storage medium of a set temperature range therein; a heat transport pipe provided between each of the multiple heat source energy production sources and the underground heat distributor and transporting a heat source produced in each of the multiple heat source energy production sources to the ground heat distributor; and a heat distribution pipe installed between the greenhouse and the underground heat distributor to distribute and supply the heat of the heat storage medium of the underground heat distributor to the greenhouse side according to growth environment conditions of the greenhouse. The present invention is to combine and store heat sources produced from various energy sources in horticultural facilities to provide an energy supply method for stable growth environment management in greenhouses.

Description

Greenhouse energy supply method and method using convergence energy production and storage technology

The present invention relates to a method for stably supplying horticultural facilities by fusion of thermal energy produced from convergence new and renewable energy sources.

In general, in facility horticulture, crops are planted in a plantation area configured inside a greenhouse such as a glass greenhouse or a plastic house, and the cultivation process is performed while managing the environment to maintain conditions such as temperature, humidity, and CO2 ideal for growing crops. .

A greenhouse is usually composed of a greenhouse frame constructed to perform the function of a skeleton, and a light-transmitting planar body made of glass or vinyl sheet installed in the greenhouse frame.

In addition, various additional facilities for controlling temperature, humidity, CO2, etc. are installed inside the greenhouse, and additional facilities such as a heating device for temperature control, a cooling device, and a CO2 supply device for supplying carbon dioxide are provided.

Most greenhouse heating systems adopt hot water heating that circulates hot water to control the internal temperature, but due to the structural characteristics of the greenhouse, a large deviation occurs in the temperature in the longitudinal or width direction, and most greenhouses are located in the central Since the overall temperature is controlled based on the temperature monitored by the sensor placed in the

As a method to solve this problem, a floor heating and cooling system for a glass greenhouse as disclosed in Korean Patent Registration No. 10-1611962 has been proposed.

The above-described floor heating and cooling system for a glass greenhouse is disposed on the floor of the glass greenhouse, and includes a floor layer having N areas; a piping pipe installed in each of the N areas of the bottom layer through which hot and cold water flows; Cold and hot water generating device for generating cold water or hot water; and a circulation pump for supplying or returning the generated cold water or hot water to the piping pipe. a flow rate control unit disposed between the circulation pump and the pipe pipe; a temperature sensor capable of measuring a temperature around the N regions, respectively; and a control unit that controls the flow rate controller based on the measured temperature to differently adjust the amount of cold water or hot water supplied to the piping pipes installed in the N areas to constantly adjust the temperature inside the glass greenhouse.

The conventional floor heating and cooling system for a glass greenhouse can reduce the temperature non-uniformity in the greenhouse to some extent by controlling the flow rate controller to differently adjust the amount of hot water supplied to the piping pipe, but there is still a limitation that is accompanied by the following problems.

First, in the conventional floor heating and cooling system for glass greenhouses, if the amount of hot water supplied to the piping pipe is increased by controlling the flow rate control unit, the amount of heat dissipation is increased to some extent, so that the temperature of the area can be increased, but the flow rate is increased in the pipe of a predetermined standard. In this case, the flow rate is increased and the hot water is quickly recovered. In this way, when the hot water is quickly recovered by increasing the flow rate, the heat of the hot water is not properly radiated to the greenhouse, but is cooled while passing through the recovery line and collected in the recovery tank, and the water in the recovery tank is reheated with a boiler, etc. Therefore, since the process of making hot water for heating and then supplying it again is repeatedly performed, there is a limitation in that the temperature rise time of the greenhouse is relatively long and energy is wasted severely.

In addition, in the conventional floor heating and cooling system for glass greenhouses, considering that the length of the longitudinal pipe of the greenhouse is very long and hot water has to go through the long pipe, even if the flow rate of hot water is increased, it is still There is a limiting point where the temperature is uneven for each area.

In addition, recently, geothermal heating and cooling systems have been developed that utilize geothermal heat with a constant temperature regardless of the seasons as a heat source for heating and cooling. A technology is being developed to use a geothermal heating and cooling system based on an alluvial aquifer that maintains about 14℃ for heating and cooling of greenhouses.

In general, a heat storage heating and cooling system using an alluvial aquifer installs a cold water well and a hot water well so that the groundwater is circulated to the alluvial aquifer, and during cooling, the ground water of the cold well is pumped to perform cooling through heat exchange through a heat pump, The hot wastewater heated by cooling is discharged to the hot water well and stored in the alluvial aquifer. During heating, the groundwater from the hot water well is pumped to perform heating through heat exchange through a heat pump, and the cold wastewater cooled by the heating is stored. It is configured to perform heating and cooling by discharging into cold water and storing it in an alluvial aquifer.

And, conventionally, a heat storage tank or a buffer tank installed on the ground was used because a function of buffering and storing the heat medium was simply required before the heat energy produced from the heat source was supplied to the greenhouse.

In the case of these above-ground structures, the efficiency of space use of horticultural facilities decreases, the use of additional piping increases due to the distance between the heat energy producer and the consumer, and there is an excessive limit of surface heat loss to the external environment with severe temperature change.

Republic of Korea registered patent 10-2000481 Republic of Korea Patent 10-2043749 Republic of Korea Patent Registration 10-1715752 Republic of Korea Patent Registration 10-1348922

Therefore, the present invention has been devised to solve the conventional problems as described above, and according to an embodiment of the present invention, a greenhouse, an indoor farm, a vertical farm, a window farm, etc. The purpose is to provide an energy supply method for stably managing the growth environment in the greenhouse by convergence and storage of heat sources produced from various energy sources in horticultural facilities, including

In addition, according to an embodiment of the present invention, in the supply of greenhouse energy, it is possible to respond to various combinations of new and renewable energy production according to regional and seasonal climatic conditions, and the time difference and temperature difference between heat sources produced from different energy sources in the previous stage of supplying greenhouse energy By buffering load fluctuations, energy is stably supplied to horticultural facilities, and through this, energy independence of horticultural facilities using new and renewable energy sources can be promoted. An object of the present invention is to provide a greenhouse energy supply system and method using convergence energy production and storage technology, which can improve efficiency.

And according to an embodiment of the present invention, the greenhouse energy supply method using the convergence energy production and storage technology transports and stores the thermal energy supplied from the convergence energy production source to the greenhouse through an underground distribution pipe and stably supplies the energy to the greenhouse. It functions as a hub and saves ground space to increase space utilization and minimize heat loss to overcome the functional limitations of existing above-ground heat storage and buffer tanks. It aims to provide a greenhouse energy supply system and method using convergence energy production and storage technology, which can improve the degree of space utilization when installing and operating a source.

According to an embodiment of the present invention, hot or cold energy is produced from various combinations of renewable and unused energy sources according to regions, climatic conditions, etc., and the imbalance in supply and demand that may occur in energy supply and production is buffered By transporting and storing it in an underground distribution pipe that can Convergence energy production and storage technology that can uniformly correct growth environment conditions according to local temperature differences in greenhouses (heat loss from walls, etc.) and enable more effective greenhouse energy management by storing or utilizing surplus heat It aims to provide a greenhouse energy supply system and method using

According to an embodiment of the present invention, by using a geothermal heat distributor, 1) it is possible to converge thermal energy produced from various renewable and unused energy sources, and 2) it is possible to save ground space by burying it in the ground around greenhouses and machine rooms. 3) It is possible to minimize heat loss during heat storage and transportation due to the stable thermal environment in the ground, and 4) If a phase change material or chemical heat storage material is used as the heat transport medium in addition to sensible heat, the transport energy density is increased and the 6) Intelligent greenhouses between supply and demand (smart farms, building farms) can minimize the heat loss caused by It aims to provide a greenhouse energy supply system and method using convergence energy production and storage technology that can broaden the scope of application to fields that can be managed.

On the other hand, the technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly to those of ordinary skill in the art to which the present invention belongs from the description below. can be understood

A first object of the present invention is, in a greenhouse energy supply system, a multi-heat source energy production source for supplying a heat source by producing energy; a geothermal heat distributor that is buried in the ground of the greenhouse and stores a heat storage medium within a set temperature range; a heat transport pipe provided between each of the multiple heat source energy production sources and the geothermal heat distributor to transport the heat sources produced in each of the multiple heat source energy production sources to the geothermal heat distributor; and a heat distribution pipe installed between the greenhouse and the geothermal heat distributor to distribute and supply heat from the heat storage medium of the geothermal heat distributor to the greenhouse side according to the growing environment conditions of the greenhouse; Convergence energy production comprising a; And it can be achieved as a greenhouse energy supply system using storage technology.

And the multi-heat source energy production source may be characterized in that it is composed of at least one of an aquifer quarterly thermal storage system, a hydrothermal energy source, a bio-boiler, and a wind energy source.

In addition, the aquifer thermal storage system includes an alluvial aquifer thermal storage unit for warming, an alluvial aquifer thermal storage unit for cooling, and energy produced by the alluvial aquifer thermal storage unit for heating and the alluvial aquifer thermal storage unit for cooling. It may include a heat pump unit that converts energy into cold and warm heat energy and supplies it to the geothermal heat distributor.

And installed near the greenhouse, further comprising a machine room having a heat pump that receives the energy produced by each of the multiple heat source energy production sources and converts it into thermal energy, and supplies thermal energy to the geothermal heat distributor through the machine room heat pump. And, it may be characterized in that the heat storage medium is stored.

In addition, the heat distribution pipe is configured in plurality to be distributed on the floor of the greenhouse, and each of the plurality of heat distribution pipes further comprises a distribution pump for individually supplying and circulating the heat storage medium, and a control valve provided in each of the plurality of heat distribution pipes. can be done with

And it may be characterized in that it further comprises a greenhouse heat supply pipe for supplying the heat energy by the machine room hip pump to the greenhouse.

In addition, the heat storage medium may be characterized in that it is composed of a phase change material or a chemical heat release material.

And it may be characterized by further comprising a plurality of temperature sensors installed for each position in the greenhouse.

In addition, a thermal storage temperature sensor for measuring the temperature of the thermal storage medium stored in the geothermal heat distributor in real time; and a control unit controlling the heat pump in the machine room based on the thermal storage temperature sensor to adjust the temperature of the thermal storage medium to be within a set temperature range.

The control unit may control the heat distribution pump, the control valve, and the heat pump so that the temperature and the temperature deviation in the greenhouse are within a set range based on the value measured by the temperature sensor.

A second object of the present invention is a method for supplying greenhouse energy, the method comprising: generating energy from each of multiple heat source energy sources; The step of supplying the energy produced through the heat transport pipe of each of the multiple heat source energy production sources to a machine room installed in the vicinity of the greenhouse; Converting the energy supplied through the heat pump installed in the machine room into thermal energy, and supplying it to the geothermal heat distributor buried underground at the greenhouse side through the heat storage supply pipe, so that the heat storage medium stored therein is maintained in a set temperature range. ; Through a heat distribution pipe installed between the greenhouse and the geothermal heat distributor, distributing and supplying the heat of the heat storage medium of the geothermal heat distributor to the greenhouse according to the growing environment conditions of the greenhouse; Convergence comprising a. It can be achieved as a greenhouse energy supply method using energy production and storage technology.

and supplying heat energy by the machine room bottom pump to the greenhouse through a greenhouse heat supply pipe installed between the greenhouse and the bottom pump.

In addition, the control unit controls the heat pump in the machine room based on a thermal storage temperature sensor that measures the temperature of the thermal storage medium stored in the geothermal heat distributor in real time to adjust the temperature of the thermal storage medium to be within a set temperature range; more It may be characterized by including.

And the heat distribution pipe is configured in plurality so as to be distributed on the floor of the greenhouse, and each of the plurality of heat distribution pipes further includes a distribution pump for individually supplying and circulating the heat storage medium, and a control valve provided in each of the plurality of heat distribution pipes, The method may further include, by a controller, controlling the heat distribution pump, the control valve, and the heat pump so that the temperature and the temperature deviation in the greenhouse are within a set range based on the value measured by the temperature sensor.

According to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, including a greenhouse, an indoor farm, a vertical farm, a window farm, etc. It has the effect of stably supplying energy for the growth environment management in the greenhouse by converging and storing the heat sources produced from various energy sources in the horticultural facility.

In addition, according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, it is possible to respond to various combinations of new and renewable energy production according to regional and seasonal climatic conditions in greenhouse energy supply, and greenhouse energy In the pre-supply stage, energy is stably supplied to horticultural facilities by buffering load fluctuations due to the time difference and temperature difference of heat sources produced from different energy sources, and through this, energy independence of horticultural facilities using new and renewable energy sources can be promoted. It has the effect of improving the efficiency of greenhouse and agricultural energy use through the management of the optimal growth environment in accordance with precision agriculture.

And according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to the embodiment of the present invention, the greenhouse energy supply method using the convergence energy production and storage technology is supplied from the convergence energy production source to the greenhouse. By transporting and storing thermal energy through an underground distribution pipe and stably supplying it to the greenhouse, it functions as an energy hub. This can be overcome, and this has the effect of improving the degree of space utilization, especially when new and renewable energy sources are installed and operated in the limited space of the primary greenhouse.

According to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, hot or cold energy is produced from various combinations of renewable and unused energy sources according to regions, climatic conditions, etc. By transporting and storing it to an underground distribution pipe that can buffer imbalances in supply and demand that may occur in energy supply and production, it is possible to stably supply hot and cold energy to the greenhouse, and through this, various heat sources (heat pumps) in the machine room , boiler, etc.) can be complexly supplied and controlled, and the growing environment conditions according to the local temperature difference in the greenhouse (heat loss from walls, etc.) can be uniformly corrected. It has the effect of making effective greenhouse energy management possible.

According to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, by using a geothermal heat distributor, 1) it is possible to converge thermal energy produced from various renewable and unused energy sources, and , 2) can be buried underground around greenhouses and machine rooms to save ground space, 3) can minimize heat loss during heat storage and transportation due to the stable underground thermal environment, and 4) heat transport medium other than sensible heat. If a changeable material or chemical heat storage material is used, it is possible to increase the transport energy density and minimize heat loss over time. 6) It has the effect of expanding the scope of application to fields that can manage intelligent greenhouses (smart farms, building farms, etc.) between supply and demand.

On the other hand, the effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. will be able

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited only to the matters described in those drawings and should not be interpreted.
1 is a conceptual diagram of a greenhouse energy supply system using a convergence energy production and storage technology according to an embodiment of the present invention;
2 is an example of greenhouse energy supply according to an embodiment of the present invention;
3 is a configuration diagram of a greenhouse energy supply system using convergence energy production and storage technology according to an embodiment of the present invention;
4 is a block diagram showing a signal flow of a control unit according to an embodiment of the present invention;
5 is a flowchart illustrating a greenhouse energy supply method using a convergence energy production and storage technology according to an embodiment of the present invention.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

In this specification, when a component is referred to as being on another component, it may be directly formed on the other component or a third component may be interposed therebetween. In addition, in the drawings, the thickness of the components is exaggerated for effective description of the technical content.

Embodiments described herein will be described with reference to cross-sectional and/or plan views, which are ideal illustrative views of the present invention. In the drawings, thicknesses of films and regions are exaggerated for effective description of technical content. Accordingly, the shape of the illustrative drawing may be modified due to manufacturing technology and/or tolerance. Therefore, the embodiments of the present invention are not limited to the specific form shown, but also include changes in the form generated according to the manufacturing process. For example, the region shown as a right angle may be rounded or have a predetermined curvature. Accordingly, the regions illustrated in the drawings have properties, and the shapes of the regions illustrated in the drawings are intended to illustrate a particular shape of the region of the device and not to limit the scope of the invention. In various embodiments of the present specification, terms such as first, second, etc. are used to describe various components, but these components should not be limited by these terms. These terms are only used to distinguish one component from another. The embodiments described and illustrated herein also include complementary embodiments thereof.

The terminology used herein is for the purpose of describing the embodiments and is not intended to limit the present invention. In this specification, the singular also includes the plural, unless specifically stated otherwise in the phrase. As used herein, 'comprises' and/or 'comprising' does not exclude the presence or addition of one or more other elements.

In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and help understanding. However, a reader having enough knowledge in this field to understand the present invention may recognize that the present invention may be used without these various specific details. In some cases, it is mentioned in advance that parts that are commonly known and not largely related to the invention are not described in order to avoid confusion without any reason in describing the present invention in describing the invention.

Hereinafter, the configuration, function and method of the greenhouse energy supply system using the convergence energy production and storage technology according to an embodiment of the present invention will be described.

The present invention relates to a method for stably supplying thermal energy to a greenhouse by using a geothermal heat distributor having a heat storage and buffer function for fusion energy produced from various renewable and unused energy sources.

The present invention relates to a greenhouse energy supply method capable of storing and stably transporting thermal energy produced from a convergence energy source to a greenhouse without loss for effective supply and management of greenhouse energy. (1) heat transport, (2) heat exchange, (3) heat storage, (4) By installing a geothermal heat distributor with a heat distribution function, it is possible to increase the efficiency of space use in horticultural facilities and to stably, scalably, and precisely manage the energy required for the management of the growing environment. reflected.

First, FIG. 1 shows a conceptual diagram of a greenhouse energy supply system using convergence energy production and storage technology according to an embodiment of the present invention. And Figure 2 shows an example of greenhouse energy supply according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, the greenhouse energy supply system 100 using the convergence energy production and storage technology according to an embodiment of the present invention includes a plurality of multiple heat source energy production sources 10 and a heat transport pipe. (30), it can be seen that the geothermal heat distributor 50, it can be configured to include a heat distribution pipe (51).

The multiple heat source energy production source 10 is for supplying a heat source by producing energy. can be configured.

The aquifer quarterly thermal storage system 20 includes a water collection well, an exponential heat injection well, and a heat pump unit 21, and as shown in FIG. It may be configured to include a thermal storage unit 20-2 in the alluvial aquifer. The energy produced in each of the alluvial aquifer quarterly heat storage unit 20-1 for warm heat and the alluvial aquifer quarterly heat storage unit 20-2 for cold heat is transferred to the heat pump unit 21 through the heat medium pipe 22.

The heat pump unit 21 converts the energy produced by the alluvial aquifer quarterly heat storage unit 20-1 for warm heat and the energy produced by the alluvial aquifer quarterly heat storage unit 20-2 for cold heat into cold and warm heat energy to generate a geothermal heat distributor ( 50).

And the geothermal heat distributor 50 is buried in the ground on the side of the greenhouse (1). The geothermal heat distributor 50 receives the energy produced by the multiple heat source energy production source 10 and stores the heat storage medium stored therein so as to be within a set temperature range.

In addition, the heat transport pipe 30 is provided between each of the multiple heat source energy production sources 10 and the geothermal heat distributor 50 to transport the heat sources produced in each of the multiple heat source energy production sources 10 to the geothermal heat distributor 50 . configured to do

And the heat distribution pipe 51 is installed between the greenhouse 1 and the geothermal heat distributor 50 to distribute the heat storage medium heat of the geothermal heat distributor 50 to the greenhouse 1 according to the growing environment conditions of the greenhouse 1, configured to supply.

3 is a block diagram of a greenhouse energy supply system 100 using a convergence energy production and storage technology according to an embodiment of the present invention. 4 is a block diagram illustrating a signal flow of the control unit 60 according to an embodiment of the present invention. In addition, Figure 5 shows a flowchart of a greenhouse energy supply method using the convergence energy production and storage technology according to an embodiment of the present invention.

As shown in FIG. 3 , the energy produced in each of the multiple heat source energy production sources 10 can be supplied through the machine room 40 installed near the greenhouse 1 , and the energy supplied in the machine room 40 is It can be seen that it includes a heat pump 43 that converts the heat into cold and hot energy.

In the embodiment of the present invention, heat energy is supplied to the geothermal heat distributor 50 buried in the bottom side of the greenhouse 1 through the heat pump 43 of the machine room 40 to store heat in the heat storage medium.

In addition, the heat distribution pipe 51 according to the embodiment of the present invention may be configured in plurality so as to be distributed on the floor of the greenhouse 1 . Therefore, it is possible to minimize the temperature deviation inside the greenhouse 1 through the heat distribution pipe 51 and to control the described growth environment.

In addition, the distribution pump 52 is configured to supply and circulate a heat storage medium individually to each of the plurality of heat distribution pipes 51 , and a control valve 53 is provided in each of the plurality of heat distribution pipes 51 to provide a flow rate of the heat storage medium supplied. By adjusting the partial temperature control of the greenhouse (1) is possible.

And as shown in FIG. 3 , it may include a greenhouse heat supply pipe 42 that directly supplies thermal energy by the heat pump 43 of the machine room 40 to the inside of the greenhouse 1 .

In addition, the heat storage medium may be configured to use a phase change material or a chemical heat release material in addition to sensible heat to increase the transport energy density and minimize heat loss over time.

And, as shown in FIG. 4 , a temperature sensor 2 is installed for each location in the greenhouse 1 to measure the temperature and temperature deviation inside the greenhouse 1 in real time.

And it may be configured to measure the temperature of the thermal storage medium stored in the geothermal heat distributor 50 through the thermal storage temperature sensor 54 in real time. Therefore, the control unit 60 controls the heat pump 43 in the machine room 40 based on the thermal storage temperature sensor 54 to adjust the temperature of the thermal storage medium to be within the set temperature range.

In addition, the control unit 60, the heat distribution pump 52, the control valve 53, and the heat pump ( 43) will be controlled. That is, it is possible to supply the heat storage medium through the heat distribution pipe 51 only to a portion with a partially low temperature, and control to supply different flow rates between a plurality of heat distributions so that the temperature deviation is minimized. By controlling the pump 43 , it is possible to adjust the amount of heat energy supplied through the greenhouse heat supply pipe 42 .

Hereinafter, a greenhouse energy supply method using a convergence energy production and storage technology according to an embodiment of the present invention will be described.

First, each of the multiple heat source energy production sources 10 produces energy (S1).

And the energy produced through the heat transport pipe 30 of each of the multiple heat source energy production sources 10 is supplied to the machine room 40 installed in the vicinity of the greenhouse 1 (S2).

In addition, the energy supplied through the heat pump 43 installed in the machine room 40 is converted into thermal energy, and supplied to the geothermal heat distributor 50 buried in the ground on the side of the greenhouse 1 through the heat storage supply pipe 41. The heat storage medium stored therein is stored so that it is maintained in a set temperature range (S3).

At this time, the control unit 60 controls the heat pump 43 in the machine room 40 based on the thermal storage temperature sensor 54 that measures the temperature of the thermal storage medium stored in the geothermal heat distributor 50 in real time to increase the temperature of the thermal storage medium. It is adjusted to be within the set temperature range.

And through the heat distribution pipe 51 installed between the greenhouse 1 and the geothermal heat distributor 50, the heat storage medium heat of the geothermal heat distributor 50 is directed to the greenhouse 1 according to the growing environment conditions of the greenhouse 1 Distribution and supply (S4, S5). In addition, through the greenhouse heat supply pipe 42 installed between the greenhouse 1 and the heat pump 43 at the same time, the heat energy by the heat pump 43 in the machine room 40 can be directly supplied to the greenhouse 1 .

As mentioned above, a plurality of heat distribution pipes 51 are configured to be distributed on the floor of the greenhouse 1, and the distribution pump 52 operates each of the plurality of heat distribution pipes 51 individually to move the heat storage medium to a desired position. The supply can be circulated, and a control valve 53 is provided in each of the plurality of heat distribution pipes 51 to control the flow rate of the supplied thermal storage medium.

That is, the control unit 60, the heat distribution pump 52, the control valve 53 and the heat pump ( 43) will be controlled.

Therefore, according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to the embodiment of the present invention mentioned above, a greenhouse, an indoor farm, a vertical farm, a window farm ), etc., by converging and storing heat sources produced from various energy sources in horticultural facilities, etc.

In addition, according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, it is possible to respond to various combinations of new and renewable energy production according to regional and seasonal climatic conditions in greenhouse energy supply, and greenhouse energy In the pre-supply stage, energy is stably supplied to horticultural facilities by buffering load fluctuations due to the time difference and temperature difference of heat sources produced from different energy sources, and through this, energy independence of horticultural facilities using new and renewable energy sources can be promoted. It will be possible to improve the efficiency of greenhouse and agricultural energy use through the management of the optimal growth environment suitable for precision agriculture.

And according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to the embodiment of the present invention, the greenhouse energy supply method using the convergence energy production and storage technology is supplied from the convergence energy production source to the greenhouse. By transporting and storing thermal energy through an underground distribution pipe and stably supplying it to the greenhouse, it functions as an energy hub. This can be overcome, and this can improve the degree of space utilization, especially when installing and operating a new renewable energy source in the limited space of the primary greenhouse.

In addition, according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, hot or cold energy is produced from various combinations of renewable and unused energy sources according to regions, climatic conditions, etc., By transferring and storing this to an underground distribution pipe that can buffer imbalances in supply and demand that may occur in energy supply and production, it is possible to stably supply cold and hot energy to the greenhouse, and through this, various heat sources (heat pumps) in the machine room , boiler, etc.) can be complexly supplied and controlled, and the growing environment conditions according to the local temperature difference in the greenhouse (heat loss from walls, etc.) can be uniformly corrected. Effective greenhouse energy management can become possible.

And according to the greenhouse energy supply system and method using the convergence energy production and storage technology according to an embodiment of the present invention, by using a geothermal heat distributor, 1) it is possible to converge thermal energy produced from various renewable and unused energy sources. 2) It is possible to save ground space by burying it in the ground around the greenhouse and machine room, 3) It can minimize heat loss during heat storage and transportation due to the stable underground thermal environment, 4) Heat transport medium other than sensible heat If a phase change material or chemical heat storage material is used, it is possible to increase the transport energy density and minimize heat loss over time. 6) It is possible to broaden the scope of application to fields that can manage intelligent greenhouses (smart farms, building farms, etc.) between supply and demand.

In addition, in the apparatus and method described above, the configuration and method of the above-described embodiments are not limitedly applicable, but all or part of each embodiment is selectively combined so that various modifications can be made. may be configured.

1: Greenhouse
2: Temperature sensor
10: Multiple heat source energy production source
11:Bio facility
12: hydrothermal energy
20: aquifer quarterly heat storage system
20-1: Aquifer quarterly heat storage unit for heat
20-2: aquifer quarterly heat storage unit for cooling
21: heat pump unit
22: heat medium piping
30: heat transport pipe
40: machine room
41: heat storage supply pipe
42: greenhouse heat supply pipe
43: heat pump
50: geothermal heat distributor
51: heat distribution pipe
52: heat distribution pump
53: control valve
54: heat storage temperature sensor
60: control unit
100: Greenhouse energy supply system using convergence energy production and storage technology

Claims (14)

In the greenhouse energy supply system,
a multi-heat source energy production source that produces energy and supplies a heat source;
a geothermal heat distributor that is buried in the ground of the greenhouse and stores a heat storage medium within a set temperature range;
a heat transport pipe provided between each of the multiple heat source energy production sources and the geothermal heat distributor to transport the heat sources produced in each of the multiple heat source energy production sources to the geothermal heat distributor; and
Convergence energy production and comprising; a heat distribution pipe installed between the greenhouse and the geothermal heat distributor to distribute and supply the heat storage medium heat of the geothermal heat distributor to the greenhouse side according to the growing environment conditions of the greenhouse Greenhouse energy supply system using storage technology.
The method of claim 1,
The multiple heat source energy production source,
A greenhouse energy supply system using a convergence energy production and storage technology, characterized in that it consists of at least one of an aquifer quarterly heat storage system, a hydrothermal energy source, a bio boiler, and a wind energy source.
3. The method of claim 2,
The aquifer thermal storage system,
The alluvial aquifer quarterly heat storage unit for warm heat, the alluvial aquifer quarterly heat storage unit for cold heat, and the energy produced by the alluvial aquifer quarterly heat storage unit for warm heat and the energy produced by the alluvial aquifer quarterly heat storage unit for cooling and heat are converted into cold and warm heat energy. A greenhouse energy supply system using convergence energy production and storage technology, characterized in that it includes a heat pump unit for supplying to the geothermal heat distributor.
3. The method of claim 2,
It is installed in the vicinity of the greenhouse, and further comprises a machine room having a heat pump that receives the energy produced from each of the multiple heat source energy production sources and converts them into thermal energy,
A greenhouse energy supply system using a convergence energy production and storage technology, characterized in that the heat energy is supplied to the geothermal heat distributor through the machine room heat pump and the heat storage medium is stored.
5. The method of claim 4,
The heat distribution pipe is configured in plurality to be distributed on the floor of the greenhouse,
A greenhouse energy supply system using a convergence energy production and storage technology, characterized in that it further comprises a distribution pump for individually supplying and circulating the heat storage medium through a plurality of heat distribution pipes, and a control valve provided in each of the plurality of heat distribution pipes.
6. The method of claim 5,
Greenhouse energy supply system using convergence energy production and storage technology, characterized in that it further comprises a greenhouse heat supply pipe for supplying thermal energy by the machine room bottom pump to the greenhouse.
6. The method of claim 5,
The heat storage medium is a greenhouse energy supply system using a convergence energy production and storage technology, characterized in that composed of a phase change material or a chemical heat release material.
6. The method of claim 5,
Greenhouse energy supply system using convergence energy production and storage technology, characterized in that it further comprises a plurality of temperature sensors installed for each location in the greenhouse.
9. The method of claim 8,
a thermal storage temperature sensor for measuring the temperature of the thermal storage medium stored in the geothermal heat distributor in real time; and
Greenhouse energy supply using convergence energy production and storage technology, characterized in that it further comprises; a control unit for controlling the heat pump in the machine room based on the thermal storage temperature sensor to adjust the temperature of the thermal storage medium to be within a set temperature range system.
10. The method of claim 9,
The control unit is
Greenhouse energy using convergence energy production and storage technology, characterized in that the heat distribution pump, the control valve, and the heat pump are controlled so that the temperature and temperature deviation in the greenhouse are within a set range based on the value measured by the temperature sensor supply system.
In the greenhouse energy supply method,
generating energy from each of the multiple heat source energy sources;
The step of supplying the energy produced through the heat transport pipe of each of the multiple heat source energy production sources to a machine room installed in the vicinity of the greenhouse;
Converting the energy supplied through the heat pump installed in the machine room into thermal energy, and supplying it to the geothermal heat distributor buried in the ground at the greenhouse side through the heat storage supply pipe, so that the heat storage medium stored therein is maintained in a set temperature range. ;
The step of distributing and supplying the heat storage medium heat of the geothermal heat distributor to the greenhouse side according to the growing environment conditions of the greenhouse through a heat distribution pipe installed between the greenhouse and the geothermal heat distributor; Convergence comprising a. Greenhouse energy supply method using energy production and storage technology.
12. The method of claim 11,
Greenhouse energy supply method using convergence energy production and storage technology, characterized in that it further comprises the step of supplying thermal energy by the machine room bottom pump to the greenhouse through a greenhouse heat supply pipe installed between the greenhouse and the bottom pump .
13. The method of claim 12,
Controlling, by a control unit, the heat pump in the machine room based on a thermal storage temperature sensor that measures the temperature of the thermal storage medium stored in the geothermal heat distributor in real time to adjust the temperature of the thermal storage medium to be within a set temperature range; further comprising Greenhouse energy supply method using convergence energy production and storage technology, characterized in that
14. The method of claim 13,
The heat distribution pipe is configured in plurality so as to be distributed on the floor of the greenhouse, and each of the plurality of heat distribution pipes further includes a distribution pump for individually supplying and circulating the heat storage medium, and a control valve provided in each of the plurality of heat distribution pipes,
Convergence, characterized in that the controller further comprises the step of controlling the heat distribution pump, the control valve, and the heat pump so that the temperature and the temperature deviation in the greenhouse are within a set range based on the value measured by the temperature sensor. Greenhouse energy supply method using energy production and storage technology.

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