KR19990000531U - Greenhouse Heating Boiler with Top-down Combustion - Google Patents

Abstract

The present invention relates to a heating boiler for a greenhouse by a top-down combustion device, a heat exchanger installed inside a combustion chamber that heats water by the heat of combustion of a top-down burner installed at the top of the boiler body, and combustion air when the top-down burner is burned on one side of the boiler body. A blower for supplying a gas, a flue gas and a flue gas discharge pipe through which the combustion gas combusted in the combustion chamber is discharged, a hot water discharge port through which hot water heated on one side wall of the boiler body is discharged by a hot water circulation pump, and one of the boiler body The water level sensor for sensing and controlling the level of water filled in the water chamber in the boiler body is attached to the side, and the hot water return port for returning the heated hot water is installed on the upper part of the boiler body, and a safety device for operating the boiler is installed. A heating boiler for greenhouses, which purifies combustion gas at a predetermined position of the boiler body. Combustion gas purifying tank formed with the printing plate and the water distribution plate is integrally installed with the hot water return port, and the gas discharge pipe is provided with a branch pipe, and at a predetermined position of the carbon dioxide supply pipe extended with the branch pipe. A suction blower and a damper installed by a carbon dioxide sensor installed inside the greenhouse are installed, and a carbon dioxide discharge pipe 26 is installed in the carbon dioxide supply pipe 20 extending with the suction blower 21 to burn the combustion gas burned in the combustion chamber. It purifies and discharges the combustion gas through the combustion gas purifier installed in the upper part of the chamber, and also promotes the growth of plants by automatically supplying the exhaust gas containing carbon dioxide to the greenhouse as it passes through the gas discharge pipe. Underground heating is performed by hot water.

Description

Greenhouse Heating Boiler with Top-down Combustion

The present invention relates to a heating boiler for a greenhouse by a top-down combustion device. More specifically, the combustion gas combusted in the combustion chamber purifies and discharges the combustion gas through a combustion gas purifying tank installed at the upper part of the boiler chamber. The present invention relates to a heating boiler for a greenhouse by a top-down combustion device that automatically supplies the exhaust gas to the greenhouse as required to pass through the gas discharge pipe to promote plant growth and to perform underground heating by heated hot water.

Conventional conventional heating boilers for water level sensor to adjust the water level filled in the water chamber 3 in the boiler body on one side of the boiler body 1 by the combustion heat of the top-down burner (2) as shown in FIG. (4) and feed water pump (5), feed water tank (6), a safety device (not shown), and the like, a heat exchanger (8) installed inside a combustion chamber (7) that heats water by combustion heat, and the boiler A blower 9 for supplying combustion air during combustion of the top-down burner 2 to one side of the body 1, a flue 10 and a waste gas discharge pipe 11 through which the combustion gas combusted in the combustion chamber 7 is discharged; Hot water outlet 13 for discharging hot water heated on one side wall of the boiler body 1 by the hot water circulation pump 12, and a hot water return port for returning hot water heated on the upper part of the boiler body 1 ( 14) is a configuration in which the relation of operation is explained as follows.

When the ignition switch (not shown) is turned on, the burner is ignited and burned by the fuel (LNG, LPG gas, kerosene) supplied to the burner 2, and the fuel is burned while the combustion air is supplied by the blower 9.

When the water filled in the heat exchanger 8 is heated by the heat exchanger 8 installed in the combustion chamber 7 by the combustion heat of the burner and becomes hot hot water, the hot water is heated to the hot water circulation pump 12. When the water is sent to the underground heating pipe (not shown) through the hot water outlet (13), the hot water cooled after heating the ground inside the greenhouse is re-supplied into the boiler body through the hot water return port (14) to exchange heat by the burner's combustion heat. Reheated at (8) is circulated through the hot water outlet 13 by the hot water circulation pump (12).

The hot water collected through the underground heating pipe and the hot water in the water chamber (3) when the water is insufficient due to leakage and evaporation, the water level detection sensor (4) detects this to operate the water supply pump (5) to the water supply tank (6) Replenish the water in the water chamber (3) in the boiler body (1).

And the combustion gas which heated the heat vent 8 installed in the combustion chamber 2 by the combustion heat of a burner is discharged to the atmosphere through a gas discharge pipe through a flue.

As described above, the conventional greenhouse heating boiler emits the combustion gas heated by the burner by the heat of combustion burned by the burner to the atmosphere as it contains toxic substances and pollutes the atmosphere, and the heated hot water only heats the land inside the greenhouse. As it only plays the role of making a plant, the growth and development of flowers and plants inside the greenhouse is photosynthesis, but the carbon dioxide needed in the confined space is affected by the growth of plants due to insufficient amount of carbon dioxide. there was.

In order to solve the above problems, the present proposal is to heat the hot water by the heat of combustion of the burner, and the combustion gas which is installed integrally with the greenhouse heating boiler containing the combustion gas containing toxic substances which are discharged into the atmosphere and pollute the atmosphere. After purifying through the tank, it is discharged to the atmosphere to prevent air pollution. Also, the exhaust gas containing carbon dioxide (CO2) passed through the tank is discharged through the gas discharge pipe, and some of the exhaust gas is transferred to the carbon dioxide sensor installed inside the greenhouse. It aims to improve the growth and development of plants or plants by assisting the photosynthetic action of plants by artificially supplying carbon dioxide (CO2) required for photosynthesis of plants artificially into the greenhouse by a suction blower operated by the suction blower.

In order to achieve the above object, the present invention provides a heat exchanger installed inside a combustion chamber that heats water by combustion heat of a top-down burner installed at an upper portion of a boiler body, and a blower for supplying combustion air during combustion of a top-down burner to one side of the boiler body. And flue and flue gas discharge pipes through which the combustion gas combusted in the combustion chamber is discharged, hot water heated by one side wall of the boiler body by a hot water circulation pump, and a boiler body on one side of the boiler body. In a greenhouse heating boiler equipped with a water level sensor for sensing and controlling the level of water filled in the water chamber, and a hot water return port for returning heated hot water on the upper part of the boiler body and a safety device for operating the boiler. A trimming plate and water distribution for purifying combustion gas at a predetermined position of the boiler body. The formed combustion gas purifying tank is integrally installed with the hot water return port, and the branch pipe is installed in the gas discharge pipe and operated by a carbon dioxide detecting sensor installed inside the greenhouse at a predetermined position of the carbon dioxide supply pipe that is installed with the branch pipe. The suction blower and the damper are installed, and the carbon dioxide supply pipe is installed to the suction blower and the extension.

1 is a cross-sectional view of a conventional greenhouse heating boiler.

2 is an overall schematic diagram of a configuration in which the heating boiler for the greenhouse of the present invention is installed.

3 is a cross-sectional view of the heating boiler for greenhouse in the present disclosure.

Figure 4 is an enlarged cross-sectional view of a purifier can be attached to the heating boiler for greenhouses in the present disclosure.

Figure 5 is an enlarged cross-sectional view of the carbon dioxide supply device attached to the heating boiler for greenhouses in the present article.

<Description of reference numerals for the main parts of the drawings>

1: Boiler body 2: Top-down burner 4: Water level sensor

7: combustion chamber 8: heat exchanger 9: blower

10: year 11: gas discharge pipe 12: hot water circulation pump

13: hot water outlet 14: hot water return port 15: trimming plate (仕切 板)

16: Water distribution plate 18: Purification container 19: Branch pipe

20: carbon dioxide supply pipe 21: suction blower 22: damper

23: carbon dioxide detection sensor

The present invention will be described with reference to FIGS. 2 to 5 as follows, and the reference numerals for the constitutions of the present disclosure are the same as those of the conventional heating boiler for convenience.

Figure 2 is an overall schematic view of the configuration of the heating boiler for greenhouses of the present invention, Figure 3 is a cross-sectional view of the heating boiler for greenhouses of the present invention, Figure 4 is an enlarged cross-sectional view of the purifying container is attached to the heating boiler for greenhouses of the present invention, Figure 5 is An enlarged cross-sectional view of the carbon dioxide supplying device attached to the heating boiler for greenhouse in the present disclosure will be described in detail as follows.

The present invention is provided with a heat exchanger (8) installed inside the combustion chamber (7) for heating the water by the heat of combustion of the top-down burner (2) installed on the top of the boiler body (1) and the top of the boiler body (1) A blower 9 for supplying combustion air at the time of combustion of 2) is attached.

One side wall of the boiler body (1) is heated hot water outlet 13 is discharged by the hot water circulation pump 12 and the hot water return port 14, the heated hot water is returned to the upper portion of the boiler body (1) Is attached and installed, one side of the boiler body (1) is attached to the water level sensor (4) for detecting and adjusting the water level filled in the water chamber in the boiler body and a safety device for operating the boiler.

In addition, in the gas discharge pipe 11 through which the combustion gas combusted in the combustion chamber 7 is discharged through the flue 10, a Y-shaped branch pipe 19 having the same diameter as the gas discharge pipe 11 is provided and the branch pipe 19 is disposed. At a predetermined position of the carbon dioxide supply pipe 20 which is extended and installed, a suction blower 21 operated by a carbon dioxide detection sensor 23 installed inside the greenhouse 25 and a damper 22 interlocked with the suction blower are installed. The carbon dioxide discharge pipe 26 is attached to the suction blower 21 and the carbon dioxide supply pipe 20 extended.

And the combustion gas in which the trimming plate 15 and the water distribution plate 16 in which the through-hole 17 which was formed soaked in water and let combustion gas pass through is formed in the predetermined position of the boiler body 1 is formed. The purifying tank 18 is integrally installed with the hot water return port 14 to purify the combustion gas so that it is discharged into the atmosphere, and is configured to artificially supply carbon dioxide (CO2) necessary for photosynthesis of plants to the inside of the greenhouse. .

Referring to the working relationship of the present proposal configured as described above are as follows.

When the ignition switch (not shown) is turned on, the burner is ignited and burned by the fuel (LNG, LPG gas, kerosene) supplied to the burner 2, and the fuel is burned while the combustion air is supplied by the blower 9.

When the water filled in the heat exchanger 8 is heated by the heat exchanger 8 installed in the combustion chamber 7 by the combustion heat of the burner and becomes hot hot water, the hot water is heated to the hot water circulation pump 12. When the water is sent to the underground heating tube 24 through the hot water outlet 13, the hot water cooled after heating the land inside the greenhouse is installed in the water purifier 18 through the hot water return port 14. Re-supplied into the purifying tank 18 and the boiler body through the heating) is reheated in the heat exchanger (8) by the heat of combustion of the burner and circulated through the hot water outlet (13) by the hot water circulation pump (12).

The hot water collected through the underground heating pipe 24 and the hot water filled in the water chamber 3 is leaked by the leakage and evaporation, and when the water is insufficient, the water level sensor 4 detects this and operates a water pump (not shown) in the water supply tank. The water level is adjusted by replenishing the water in the water chamber 3 in the boiler body 1.

And the combustion gas which heated the heat vent 8 installed in the combustion chamber 2 by the combustion heat of a burner is discharged to the atmosphere through the gas discharge pipe 11 after passing through the flue 10.

At this time, the hot combustion gas passing through the flue after heating the heat vent 8 installed in the combustion chamber (2) by the combustion heat of the burner as shown in Figure 4 is inside the purifier (18) submerged in water. While heating the low temperature hot water supplied from the hot water return port 14 while foaming through the through hole 17 of the installed trimming plate 15, toxic substances such as soot contained in the combustion gas are dissolved or purified in the water. It is discharged through the gas discharge pipe 11 to reduce the air pollution.

In addition, as shown in FIG. 5, the high-temperature combustion gas that has heated the low-temperature hot water supplied from the hot water return port 14 passes through a purification tank 18, and the purified low-temperature exhaust gas is provided through the gas discharge pipe 11. If the carbon dioxide required for photosynthesis of plants in the greenhouse falls below the set value while being discharged, the carbon dioxide detecting sensor 23 installed in the greenhouse detects this and operates the suction blower fan 21, so that the suction power of the suction blower fan 21 is increased. The damper 22 is opened by the passage and passes through the Y-shaped branch pipe 19 connected to the gas discharge pipe 11, and then partially through the carbon dioxide discharge pipe 26 via the carbon dioxide supply pipe 20 and the suction blower 21. By artificially supplying the carbon dioxide contained in the purified exhaust gas to the greenhouse, it helps plant and photosynthesis to promote plant growth.

The present invention heats hot water by the combustion heat of the burner, and returns hot water during the combustion gas purifier, which is installed integrally with the greenhouse heating boiler and the hot combustion gas containing toxic substances discharged into the atmosphere to pollute the atmosphere. The hot water supplied from the ward is heated and simultaneously purified and discharged to the atmosphere to prevent air pollution. Also, exhaust gas containing carbon dioxide (CO2), which has passed through the filtration tank, is discharged through the gas discharge pipe, and some of the exhaust gas is The suction blower operated by the carbon dioxide sensor installed inside the greenhouse artificially supplies carbon dioxide (CO2) necessary for plant photosynthesis to the inside of the greenhouse artificially to help photosynthesis of plants and improve the growth of plants and plants. It works.

Claims (2)

A heat exchanger 8 installed inside the combustion chamber 7 that heats water by the heat of combustion of the top-down burner 2 installed above the boiler body 1, and a top-down burner 2 on one side of the boiler body 1. Blower 9 for supplying combustion air during combustion, flue 10 and gas discharge pipe 11 through which combustion gas combusted in the combustion chamber 7 is discharged, and hot water heated on one side of the boiler body 1 The hot water outlet 13 discharged by the hot water circulation pump 12, and the water level sensor 14 for detecting and adjusting the water level filled in the water chamber in the boiler body on one side of the boiler body (1), and the boiler In a conventional greenhouse heating boiler, in which a hot water return port 14 is installed to return heated hot water to an upper portion of the body 1, and a safety device for operating the boiler is installed. A combustion gas purifier 18 having a trimming plate 15 and a water distribution plate 16 for purifying combustion gas at a predetermined position of the boiler body 1 is provided with a hot water return port 14. Heating boiler for greenhouse by the top-down combustion apparatus, characterized in that is installed integrally with. The method of claim 1, The gas discharge pipe 11 is provided with a branch pipe 19, At a predetermined position of the branch pipe 19 and the carbon dioxide supply pipe 20 extending therein, a suction blower 21 and a damper 22 operated by the carbon dioxide sensor 23 installed inside the greenhouse are installed. The inlet blower 21 and the carbon dioxide supply pipe 20 extending to be installed in the greenhouse heating boiler by the top-down combustion apparatus, characterized in that the carbon dioxide discharge pipe 26 is installed.