KR102667124B1 - Heating system for vinyl house using multi-boilers - Google Patents

Abstract

The present invention is a repeated process of arranging a plurality of boilers that store heat from solar energy in a greenhouse, operating one of the boilers, shutting it off when the temperature falls below a set temperature, and then preheating and operating the other boiler at the same time. It is configured to open the electromagnetic valve of the boiler when the boiler is in operation and close the electromagnetic valve of the boiler when it is shut off, and the hot water of the boiler is supplied and recovered through hot water circulation lines arranged in various forms within the greenhouse. The present invention is intended to provide a heating system for a greenhouse using multiple boilers, wherein a plurality of boilers that accumulate heat from sunlight are placed in a greenhouse, and when one of the boilers is operated and the temperature falls below the set temperature, the present invention provides a heating system for a greenhouse using multiple boilers. It is a very useful invention that repeats the process of blocking, then preheating, and simultaneously operating another boiler to ensure that the temperature in the plastic sewage is always maintained at a constant level, allowing uniform growth of crops and even harvesting.

Description

Heating system for vinyl house using multi-boilers}

The present invention relates to a heating system for a greenhouse using multiple boilers. More specifically, a plurality of boilers that store heat from sunlight are arranged in a greenhouse, and if the temperature falls below the set temperature after operating one of the boilers, Heating of a greenhouse using multiple boilers, which allows uniform growth and even harvesting of crops by repeating the process of blocking, then preheating, and simultaneously operating another boiler to ensure that the temperature in the plastic sewage is always kept constant. It's about the system.

In general, greenhouses are intended to increase the added value of cultivated crops by artificially creating crop growth conditions during seasonal periods when crop growth is difficult. They are usually constructed by covering the outer surface of an arch-shaped frame with vinyl.

In addition, greenhouses cannot be expected to provide great thermal insulation with just plastic to block the inflow of outside air. If the temperature drops at night, crop growth slows down and yields decrease. Therefore, depending on the region or crops grown, a separate heating device is used at night. So we are providing heating.

Prior technologies for such greenhouse heating devices include Registered Utility Model No. 20-0282350 ‘Vinyl House Heating Device’, Registered Utility Model No. 20-0307056 ‘Heating Device for Green House’, and Registered Utility Model No. 20-0475472 ‘Vinyl House Heating Device’. Examples include 'auxiliary heating device for houses', but Registered Utility Model No. 20-0282350 is to install heating wires and heating pipes with heating water inside the greenhouse to achieve internal heating, and is a registered utility model. No. 20-0307056 installs a boiler and electric heater to operate alternately inside a greenhouse, and Registered Utility Model No. 20-0475472 installs several auxiliary heating devices on the inner floor of a greenhouse. Although one boiler and several heating devices to complement the boiler are used in parallel, the hot water supplied from the boiler is composed of a circulation system that circulates inside the greenhouse and is returned to the original boiler, resulting in a considerable amount of damage. Since it was difficult to maintain a constant temperature within the long greenhouse, there was a problem that it interfered with the even growth of crops and led to the occurrence of diseases.

In addition, various other heating means are being added to reduce temperature variation within greenhouses, but not only is there an economic burden due to the installation cost of the above additional means, but there is also a problem in that it is difficult to expect maximization of heating efficiency with the conventional heating system. .

Meanwhile, when growing crops such as strawberries in a greenhouse, they are grown using high-soil cultivation equipment installed inside the greenhouse. These high-soil cultivation equipment has various structures and configurations, but most of them are grown in a vertical direction from the ground. It consists of a support installed as a support frame, a support frame for seating pots, etc. on the top of the support, and a bed that is placed on the top of the support frame, and crops are planted and cultivated on the bed.

Accordingly, after much research and effort, the present applicant placed a number of boilers that are heated by solar energy during the day in a greenhouse, starts and shuts off one of the stored boilers, and preheats again, while the other boiler operates in the front. We have come to develop a heating system that consists of a repetitive process that starts at the same time as the boiler is shut off.

Domestic registered utility model No. 20-0282350 (July 5, 2002) Domestic registered utility model No. 20-0307056 (2003.02.27) Domestic registered utility model No. 20-0475472 (2014.11.27)

The present invention is intended to solve the above problems. A plurality of boilers that store heat from solar energy are placed in a greenhouse. After operating one of the boilers, when it falls below the set temperature, it is shut off and then preheated. The purpose is to provide a heating system for a greenhouse using multiple boilers, which allows uniform growth and even harvesting of crops by repeating the process of operating another boiler to ensure that the temperature in the plastic wastewater is always maintained constant. There is.

The heating system for a greenhouse using multiple boilers according to the present invention to achieve the above object is to arrange a plurality of boilers that accumulate heat using solar energy in the greenhouse, and after operating one of the boilers, the temperature is lower than or equal to the set temperature. It consists of a repetitive process of shutting off and then preheating and operating another boiler at the same time. When the boiler is running, the electromagnetic valve of the boiler is opened and when the boiler is blocked, the electromagnetic valve of the boiler is closed. Hot water is characterized in that it is supplied and recovered through hot water circulation lines arranged in various forms within the greenhouse.

In addition, the hot water pipe of another one of the boilers is characterized by being buried longitudinally in the ground on both outer sides of the greenhouse through the ground inside the greenhouse.

In addition, the ∩-shaped framing frame of the greenhouse is composed of two layers, inner and outer, and an air layer is formed between the vinyl sheets as much as the thickness of the outer framing frame due to the vinyl covering the inner framing frame and the vinyl covering the external framing frame. It is characterized in that it is configured to be formed.

In addition, the structural frame is characterized in that it is composed of a square pipe shape other than a circular pipe.

In addition, a pair of support frames are installed longitudinally at a predetermined interval from 1 o'clock to 2 o'clock and 10 to 11 o'clock of the external structural frame, and a solar panel is seated on the support frames. It is characterized in that it is configured to be combined.

The present invention places a plurality of boilers that store heat using solar energy in a greenhouse, and after operating one of the boilers, when it falls below the set temperature, it is shut off, and then the process of preheating and operating the other boiler is repeated. By ensuring that the temperature within the plastic sewage is always maintained at a constant level, uniform growth and even harvesting of crops can be expected.

In addition, the present invention consists of an inner and outer double layer of the ∩-shaped framing frame, and as a result, an air layer is formed between the inner and outer framing frames, so that an insulating and warming effect due to the air layer can be expected, and the two layers of the framing frame The heavy structure can be expected to improve strength and durability for solar panel installation.

In addition, the present invention prevents external cold waves from penetrating into the greenhouse through the ground outside the greenhouse by burying hot water pipes in the ground on both outer sides of the greenhouse in the longitudinal direction of the greenhouse to supply hot water. This has the effect of blocking snow from accumulating on the ground outside of the source.

Figure 1 - Boiler arrangement diagram of the heating system of a greenhouse according to the present invention.
Figure 2 - Cross-sectional structural diagram of the heating system of a greenhouse according to the present invention.
Figure 3 - A perspective view and partially enlarged cross-sectional view showing the structural frame of the heating system of a greenhouse according to the present invention.
Figure 4 - A perspective view and partially enlarged cross-sectional view showing the installed state of the solar cell panel of the greenhouse heating system according to the present invention.

The present invention for achieving the above-described purposes and effects will be described in more detail through preferred embodiments as follows.

In the greenhouse heating system using multiple boilers according to the present invention, a plurality of boilers (10) that accumulate heat from sunlight are placed in the greenhouse, and after operating one of the boilers (10-1), the set temperature is set. If it falls below this level, it is shut off, then preheated and simultaneously operates another boiler (10-2), which is a repetitive process. When the boiler (10) is in operation, the electromagnetic valves (11a, 12a) of the corresponding boiler are opened and when shut off, the boiler (10) is operated. is configured to close the electromagnetic valves (11a, 12a) of the boiler, and the hot water of the boiler (10) is configured to be supplied and recovered through the hot water circulation line (A) arranged in various forms within the greenhouse.

[Figure 1] shows the boiler arrangement structure of the greenhouse heating system according to the present invention. In the present invention, three boilers are shown, but it is natural that there is no limit to the number of boilers depending on the heating scale of the greenhouse. I will do it.

The boiler 10 is an electric boiler that stores heat using sunlight during the day, and is usually stored at a temperature of 70 to 90 degrees Celsius using solar energy, a type of renewable energy.

The boilers 10 are arranged in large numbers in the greenhouse on the left and right at the inlet side, left and right on the outlet side, left and right on the middle side depending on the length of the greenhouse, and the boilers 10 arranged in this way are arranged in parallel and circulate hot water inside the greenhouse. The line (A) is shared.

That is, one of the boilers (10-1) is operated, and at this time, the electromagnetic valves (11a, 12a) of the boiler (10-1) are opened to create a hot water circulation line consisting of a hot water supply pipe (11) and a hot water return pipe (12). Hot water is circulated through (A), and when the hot water temperature of the boiler (10-1) falls below the set temperature, operation is stopped and the electromagnetic valves (11a, 12a) are closed and preheating begins.

Simultaneously with the preheating of the boiler (10-1), the other boiler (10-2) is operated by opening the corresponding electromagnetic valves (11a, 12a). At this time, the hot water circulation line ( By sharing A), hot water from the currently operating boiler (10-2) is circulated within the greenhouse, thereby maintaining a constant temperature within the greenhouse.

In addition, when the hot water in the boiler (10-2) falls below the set temperature, it is blocked through the electromagnetic valves (11a, 12a) and at the same time preheating begins, and along with the preheating, another boiler (10-3) The heating system is made up of a repetitive process in which the first boiler 10-1, which has finished operating or preheating, is restarted.

In addition, the boilers (10-1, 10-2, and 10-3) are equipped with a temperature control device (10-1a, 10-2a, 10-3a) and a time control device (10-1b, 10-2b, 10-3), respectively. 3b) is deployed, and at this time, the temperature control device checks the hot water temperature of the relevant boiler, and if it falls below the set temperature, stops the boiler from operating and controls it to enter a preheating state. In addition, other boilers that have completed heat storage and preheating are operated. The time control device collects data on repeated operation, stop, and preheating of the boiler through the temperature control device and analyzes the data to control the operation, stop, and preheating of the boiler at the optimal time.

Meanwhile, [Figure 2] shows a cross-sectional structural diagram of the heating system of a greenhouse according to the present invention, and the hot water pipe 10-3c of another boiler 10-3 among the boilers 10 is vinyl. It is configured to be buried longitudinally in the ground on both outer sides of the greenhouse through the ground inside the house. This means that no heating means has been used in the ground between the ground on both outer sides of a single-building greenhouse and a multi-building greenhouse. Because it is not formed, if the ground on both sides of the greenhouse or the ground between the greenhouses freezes during cold weather, the cold wave will penetrate into the greenhouse, so this is a necessary configuration to prevent this.

That is, by burying hot water pipes in the ground on both outer sides of the greenhouse in the longitudinal direction and supplying hot water to the hot water pipes, cold waves from the outside are prevented from penetrating into the greenhouse, and the ground is prevented from freezing during extreme cold weather. Furthermore, it prevents snow from accumulating.

In addition, the hot water pipe of another boiler among the boilers 10 has a structure in communication with the frame of the high-soil cultivation equipment B arranged in large numbers in the greenhouse or the frame frame 20 forming the frame of the greenhouse. It may be configured. Of course, at this time, it is natural that the hot water pipe does not share the hot water circulation line (A) mentioned above, but consists of a separate hot water supply pipe and a hot water return pipe.

On the other hand, [Figure 3] is a perspective view and a partially enlarged cross-sectional view showing the structural frame of the heating system of the greenhouse according to the present invention, wherein the ∩-shaped structural frame 20 of the greenhouse is composed of an inner and outer double layer, It is configured to form an air layer (20a) between the vinyl covering the inner framing frame 21 and the vinyl covering the outer framing frame 22, as much as the thickness of the external framing frame 22.

That is, the internal and external framing frames 21 and 22 are composed of a ∩-shaped basic frame and a plurality of connecting frames arranged in the longitudinal direction connecting the basic frame. At this time, the internal framing is used to increase the strength and durability of the framing frame. It is desirable to arrange the ∩-shaped basic frame of the external structural frame 22 between the ∩-shaped basic frames of the frame 21.

In addition, as confirmed in the partially enlarged cross-sectional view shown in [FIG. 4] by the vinyl covered on the internal framing frame 21 and the vinyl covered on the external framing frame 22, a plurality of structures are formed by the basic frame and the connecting frame. An air layer 20a consisting of a partition wall is formed, and the insulation and heat retention effects of the greenhouse can be expected by the air layer 20a.

In addition, the framing frame 20 may be composed of a square pipe shape other than a circular pipe, which means that when vinyl is covered on a framing frame made of a circular pipe shape, the vinyl is conventionally fixed using clips, but the framing frame ( When 20) is configured in the shape of a square pipe, the use of existing clips is excluded and adhesive is applied to the outer surface of the frame frame 20, and then the contact area of the vinyl is required to adhesively fix the vinyl in a tensioned state. It can be configured.

On the other hand, [Figure 4] shows a perspective view of the solar cell panel of the heating system of the greenhouse according to the present invention installed, in the direction from 1 o'clock to 2 o'clock and from 10 o'clock to 11 o'clock of the external framing frame 22. A pair of support frames 22a are installed in the longitudinal direction at a predetermined interval, and the solar panel 30 is seated and coupled to the support frames 22a. In this case, the support frames 22a Installing in the 1 o'clock to 2 o'clock and 10 to 11 o'clock directions rather than the 12 o'clock direction of the external framing frame (22) is installed into the greenhouse by the solar panel (30) coupled to the support frame (22a). This is to prevent the incoming sunlight from being blocked.

That is, the purpose is to allow sunlight to flow into the greenhouse during the day into the remaining areas except for the area where the solar panel 30 is installed, and to charge solar energy through the solar panel 30.

As described above, although the present invention has been described in terms of limited embodiments, the present invention is not limited thereto, and the technical idea of the present invention and the patents described below will be recognized by those skilled in the art. Various modifications and variations are possible within the scope of equivalence of the claims.

* Explanation of symbols for main parts of the drawing *
10: Boiler 10-1: Boiler 1
10-2: Boiler 2 10-3: Boiler 3
10-1a, 10-2a, 10-3a: Temperature control device
10-1b, 10-2b, 10-3b: Time control device
11: hot water supply pipe 12: hot water return pipe
11a, 12a: Electronic valve 20: Skeleton frame
20a: air layer 21: internal structural frame
22: External structural frame 30: Solar panel
A: Hot water circulation line B: High-soil cultivation device

Claims (5)

A plurality of boilers (10) that store heat using solar energy are placed in a greenhouse. After operating one of the boilers (10-1), if it falls below the set temperature, it is shut off and then preheated, and at the same time, the other boiler (10-1) is operated. It consists of a repetitive process of operating 10-2), and when the boiler 10 is in operation, the electromagnetic valves 11a and 12a of the boiler are opened and when the boiler 10 is shut off, the electromagnetic valves 11a and 12a of the boiler are closed. , the hot water of the boiler 10 is configured to be supplied and recovered through a hot water circulation line (A) consisting of a hot water supply pipe 11 and a hot water return pipe 12 arranged in various shapes within the greenhouse;
The hot water pipe (10-3c) of another boiler (10-3) among the boilers (10) is configured to be buried longitudinally in the ground on both outer sides of the greenhouse through the ground within the greenhouse;
The ∩-shaped framing frame (20) of the greenhouse is composed of an inner and outer frame of an internal framing frame (21) and an external framing frame (22), and the vinyl covering the internal framing frame (21) and the external framing frame ( 22) is configured so that an air layer (20a) is formed between the two vinyl pieces as much as the thickness of the external framework frame (22) by the vinyl covering the framework frame (20), and the framework frame (20) is configured in the shape of a square pipe;
A pair of support frames (22a) are installed in the longitudinal direction at a predetermined interval from 1 o'clock to 2 o'clock and 10 to 11 o'clock of the external framing frame 22, and the support frames (22a) A heating system for a greenhouse using multiple boilers, characterized in that the solar panel (30) is configured to be seated and combined. delete delete delete delete