KR200412493Y1 - The hot air heating system for agricultural - Google Patents

Abstract

The present invention relates to a device for supplying hot air for maintaining a constant temperature of a room, such as a greenhouse, a greenhouse, a greenhouse, a greenhouse, a variety of greenhouses, a greenhouse, a body (10), a heater (20), a chamber ( 30), the heat insulating material 40 and the control panel 50 are made into a main structure. The main body 10 includes a blower 15 having a flow path of air through the frame 11 in multiple stages and introducing external air from the upper inlet 12 and sending it to the outlet 13 of the side. Install. The heater 20 is installed to be adjacent to a plurality of discharge ports 13 in the main body 10, and is provided in an aero-fin type that generates heat by electricity. The chamber 30 is mounted in a zigzag manner between the heaters 20, and heat medium oil 31 is filled therein to collect heat. The heat insulating material 40 is installed to seal the flow path of the main body 10 and is insulated by blocking heat generated from the heater from the outside. The control panel 50 detects the hot air temperature generated by the heater 20 with the sensor 51 and controls the operation according to the set sequence connected to the circuit.

Accordingly, the present design, unlike the conventional hot air, improves the supply of hot air in the state of staying as much as possible while using a chamber in which the fin heater and the heat medium oil are introduced, so that the hot air is supplied quickly with the minimum power consumption, and thus the heat transfer effect and Excellent thermal efficiency and low power consumption can greatly reduce fuel costs, and its structure is simple, easy to maintain and manage, and does not generate harmful gases, thereby providing a pleasant hot air.

Agriculture, Green House, Barn, Drying, Heater, Chamber, Blower, Hot Air, Maintenance, Management

Description

The hot air heating system for agricultural}

1 is a perspective view showing a hot air blower of the present invention.

Figure 2 is a block diagram showing the inside of the hot air fan of the present invention in cross section.

3 is a configuration diagram showing a hot air blower of the present invention in a plane.

※ Explanation of main parts of drawing ※

1: heat fan 10: main body

11: frame 15: blower

20: heater 30: chamber

31: heat medium oil 40: insulation

50: control panel 51: temperature sensor

A: Air H: Hot Air

The present invention relates to a hot air blower, and more specifically, unlike a conventional hot air blower, by using a chamber in which a fin heater and a heat medium oil are introduced, the hot air is improved to be supplied in a state where the hot air stays as much as possible, so that the hot air can be quickly generated with a minimum power consumption. It is supplied with excellent heat effect, heat efficiency and low power consumption, which can greatly reduce fuel costs, and its structure is simple, so it is easy to maintain and manage, and it does not generate harmful gas. It is about.

In general, a vinyl house, a greenhouse or a barn is required to maintain a constant temperature at all times in a room, and in order to meet the demand, a heating device that can supply warm air, that is, a situation in which a hot air fan is needed. In such agricultural hot air fans, economical demand is required. Most hot air currents generate hot air using expensive fuels such as petroleum and briquettes, which are highly dependent on the type of fuel used in hot air.

On the other hand, a hot air fan using oil such as petroleum (white kerosene) makes the indoor air more cold due to the disadvantage of having to ventilate the room due to the smell of oil at the time of starting or stopping, thus consuming oil to compensate for the heat lost. As the fuel costs are increased, the economic burden is great. In addition to the amount of heat used for heating, there is a closed end that the thermal efficiency is lowered because the amount of heat released through the exhaust gas into the atmosphere is very large. In addition, in the process of burning fuel, the oil is frequently incompletely burned, so that toxic gases such as sulfur or carbon dioxide are generated in the human body, and there is a risk of fire.

In addition, in the case of a hot air fan using briquettes, there are insufficient devices for releasing harmful gases generated during briquette combustion, and thermal efficiency is not sufficiently generated due to incomplete combustion. Not only was it cumbersome, but it was also inconvenient to manage, with day and night waiting to replace the briquettes. In addition, the air inside the house becomes turbid due to various harmful gases (briquette gas) generated during combustion for a long time, and the risk of safety accidents due to harmful gases is present.

In addition, in recent years, a hot air fan using electric energy has been developed and spread. However, most electric hot air fans have a risk of fire due to overheating of the electric heating element and the hot air fan itself, and the power consumption is large, resulting in low thermal efficiency. Due to the ventilation of the house, the temperature inside the house is too high, causing crops to dry or to hinder growth.

Accordingly, the present invention is to fundamentally solve the conventional problems as described above, and unlike the conventional hot air blower, the fin heater and the heat medium oil are introduced into the chamber, and the hot air is improved to be supplied in the maximum staying state. The hot air is quickly supplied by the power consumption, and the heat transfer effect and heat efficiency are excellent, and the power consumption is low, which not only can greatly reduce the fuel cost, but also the simple structure makes it easy to maintain and manage, and it does not generate harmful gas. Its purpose is to provide agricultural hot air supply.

In order to achieve the above object, the present invention provides a device for supplying hot air for maintaining a room temperature at a constant temperature in a farm cultivation facility such as various vinyl houses or greenhouses, a barn, a dryer, and the like: A main body 10 having a multi-stage air flow path, and having a blower 15 for introducing external air from the upper inlet 12 to be discharged to the outlet 13 of the side; A heater 20 interposed between a plurality of discharge ports 13 in the main body 10 and provided as an aero-pin type that generates heat by electricity; A chamber 30 interposed between the heaters 20 in a zigzag manner and having heat medium oil 31 filled therein to collect heat; A heat insulator 40 installed to seal the flow path of the main body 10 to insulate the heat generated from the heater from the outside; And a control panel 50 which detects the hot air temperature generated by the heater 20 with the sensor 51 and controls the operation according to a set sequence connected in a circuit.

At this time, the heat insulating material 40 is installed to seal the flow path through which air flows in the main body 10 by using the cerac wool 41 and the asbestos cloth 42 in double to be blocked from the outside.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

1 is a perspective view showing a hot air blower of the present invention, Figure 2 is a configuration diagram showing the inside of the hot air blower of the present invention in a cross-sectional view, Figure 3 is a block diagram showing a hot air blower of the present invention in a plan view.

The present invention relates to a device for supplying hot air for maintaining a constant temperature of a room, such as a greenhouse, a greenhouse, a greenhouse, a greenhouse, a variety of greenhouses, a greenhouse, a body (10), a heater (20), a chamber ( 30), the heat insulating material 40, the control panel 50 is the main configuration.

The main body 10 according to the present invention is provided with a flow path of air via the frame 11 in multiple stages therein, and blowers for introducing external air from the inlet 12 of the upper side and sending it to the outlet 13 of the side Install (15). The main body 10 is provided with the frame 11 in multiple stages as shown in FIGS. 1 to 2 to form a flow path to circulate air, and the inlet 12 and the outlet 13 of the side are in communication with each other. The main body 10 is provided with a blower 15 directly below the inlet 12, when the air flows into the discharge port 13 through the flow path. At this time, the heat insulating material 40 to be described later is installed in the flow path of the main body 10 so that the heat source is not leaked to the outside.

In addition, the heater 20 according to the present invention is provided with a plurality of interposed adjacent to the discharge port 13 in the main body 10, it is provided with an aero-pin type that generates heat by electricity. The heater 20 is formed of an aero-fin type (AERO-FIN). Although not shown in detail through the drawings, the heating wire is a non-exposed type of heating wire that is not exposed to the heating wire, and a space between the protection tube and the heating wire is inserted into the center of the metal protective tube. Magnesha is a heat pipe that insulates the heating wire and the protection tube by filling and compressing the insulating powder. A heat sink is installed on the outer surface. Since the heat sink helps to generate heat of the heater 20, the heat sink may be heated to a rapid temperature with the extension of the heater life. Such a heater 20 is formed in a 'M' shaped structure as shown in the enlarged view of FIG. 2 and manufactured to have high thermal efficiency even in a narrow space, and a plurality of heaters 20 are located at a lower portion of the flow path adjacent to the discharge port 13 in the main body 10. Is installed.

In addition, the chamber 30 according to the present invention is mounted with a plurality of zigzag between the heater 20, and the heat medium oil 31 is filled therein to collect heat. The chamber 30 is formed to be sealed by filling the heat medium oil 31 therein as shown in the enlarged view of FIG. 2, and is mounted in a zigzag form between the plurality of heaters 20. The chamber 30 absorbs the heat generated by the heater 20 and keeps it in a collected state, thereby preventing the hot air from cooling in a short time, and the outside air introduced into the inlet 12 by the blower 15. Air (hot air) warmed through the heater 20 serves to discharge to the discharge port 13 in the state that the maximum stay by the plurality of chambers (30).

In addition, the heat insulating material 40 according to the present invention is installed to seal the flow path of the main body 10 and is insulated by blocking heat generated from the heater from the outside. As shown in FIG. 2, the heat source is formed to maximize heat insulation while minimizing heat loss on the flow path of the main body 10 such that the heat source is not leaked to the outside. That is, the heat insulator 17 is double installed as shown in the enlarged view of FIG. 2, which minimizes the heat loss of the hot air blower 1 while releasing heat from the body 10 to the outside to maximize the heat insulation function. It performs the function to secure the maximum insulation function to block the product. The heat insulating material 40 is double-sealed by using a cerak wool (cerak wool) 41 and asbestos cloth 42 is installed to be blocked from the outside, but formed of an eco-friendly heat insulating material of non-asbestos, such as polyurethane foam or glass wool It is desirable, but not by way of limitation.

In addition, the control panel 50 according to the present invention detects the hot air temperature generated by the heater 20 with the sensor 51, and is connected to the circuit to control the operation according to the set sequence. The control panel 50 is installed inside one side of the main body 10 as shown in FIG. 2, and is connected to the blower 15 and the heater 20 in a circuit. The control panel 50 is controlled by detecting the hot air temperature and the room temperature in the main body 10 with the sensor 51. The sensor 51 is a hot air temperature in the main body 10 as shown in FIG. Although installed in the vicinity of the installation, although not shown through the drawings, the sensor is provided to detect the temperature of the room, respectively. The sensor maintains the hot air temperature and the room temperature at an appropriate temperature, and is controlled by the control panel 50. In this case, as shown in FIG. 1, the control panel may control an on / off key for controlling a power supply, an on / off key for controlling a power supply of the blower 15, and a power supply for the heater 20. A display unit for displaying an indoor temperature and a hot air temperature is provided, along with various control keys such as an on / off key and an emergency stop key for immediate stop.

In operation through FIGS. 1 to 3, first, when power is supplied to the hot air blower 1 in FIG. 1, the blower 15 and the heater 20 operate. Subsequently, the blower 15 is operated as shown in FIG. 2 to allow the external air A to flow from the inlet 12 and to be discharged to the discharge port 13 through the flow path. When the heater 20 generates heat, the outside air A introduced through the flow path is heated, and the heated air H is adjustable by the control panel 50 and maintained at about 120 to 170 ° C.

At this time, the heat generated by the heater 20 is kept in a state in which the chamber 30 absorbs and collects the heat and prevents cooling of the hot air within a short time, and the heat source emitted by the heater 20 by the chamber 30 is prevented. The air (hot air) H, which can be transmitted more reliably, is sent out to the discharge port 13 in the state where it stays as much as possible by the plurality of chambers 30. In addition, the flow path through which air flows minimizes the heat loss of the hot air blower 1 by the double insulator 17 installed therein, so that heat in the main body 10 is not discharged to the outside, thereby minimizing heat source loss. At this time, the control panel 50 maintains the hot air temperature and the room temperature at an appropriate temperature by the sensor.

As such, the hot air (H) sent to the discharge port 13 is connected to each of the discharge pipe 13 to the plastic pipe (P) to supply to a predetermined space, which is cultivated inside the greenhouse or greenhouse for growing crops and flowers By supplying hot air to the flower complex to maintain the proper temperature necessary for the growth of crops.

As described above, the agricultural hot air fan 1 of the present invention generates a hot air using the heater 20 of the AERO-FIN type and the chamber 30 in which the heat medium oil 31 is enclosed and thus stays as large as possible. Hot air is supplied quickly with minimal power consumption, and the fuel cost is greatly reduced due to excellent heat transfer effect and thermal efficiency and low power consumption. In addition, the hot air blower 1 of the present invention has a simple structure, as shown in FIG. 2, and is easy to maintain and manage, and unlike conventional hot air blowers (petroleum or briquettes), no harmful gas is generated to generate electricity. Hot air is supplied.

It is apparent to those skilled in the art that the present invention is not limited to the embodiments described, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or modifications will have to belong to the utility model registration claims of the present invention.

As described above, the present invention, unlike the existing hot air, improves the supply of hot air in the state of staying as much as possible while using a chamber in which the fin heater and the heat medium are ingested, and thus, the hot air is supplied quickly with the minimum power consumption. It has excellent thermal efficiency and low power consumption, which not only can greatly reduce fuel costs, but also its simple structure makes it easy to maintain and manage, while providing no harmful gases.

Claims (2)

In a plant for growing crops such as various greenhouses and greenhouses, and a device for supplying hot air to keep the indoor temperature at a constant temperature in a barn or a dryer: A main body 10 having a flow path of air through the frame 11 in multiple stages therein, and having a blower 15 for introducing external air from the upper inlet 12 and sending it to the discharge port 13 on the side surface 10. ); A heater 20 interposed between a plurality of discharge ports 13 in the main body 10 and provided as an aero-pin type that generates heat by electricity; A chamber 30 interposed between the heaters 20 in a zigzag manner and having heat medium oil 31 filled therein to collect heat; A heat insulator 40 installed to seal the flow path of the main body 10 to insulate the heat generated from the heater from the outside; And And a control panel (50) which detects the hot air temperature generated by the heater (20) with the sensor (51) and controls the operation according to a set sequence connected in a circuit. The method of claim 1, The heat insulating material 40 is an agricultural hot air blower, characterized in that the air flow in the body 10 is installed so as to seal the double flow path using the cerak wool (41) and asbestos cloth (42) to be blocked from the outside.

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