KR101460067B1 - Hot air supplying apparatus for glasshouse - Google Patents

Abstract

The present invention relates to a glasshouse that has improved hot air supply efficiency and ventilation efficiency. The present invention provides a hot air supply apparatus for a glasshouse including a boiler that includes a main body which has an inner heating space and a burner which is disposed on one side of the main body, a compressed air storage unit that is disposed out of the main body and stores compressed air therein, and a compressed air supply pipe that has one end connected to the compressed air storage unit, the other end portion communicating with an inner portion of the glasshouse, and one side passing through the heating space of the main body, in which the burner heats the one side of the compressed air supply pipe passing through the heating space so as to convert the compressed air passing through the compressed air supply pipe into hot air. According to the present invention, the compressed air supplied into the glasshouse through the compressed air supply pipe is heated and the supply of the hot air into the glasshouse is facilitated by an expansion force of the compressed air. Accordingly, the hot air can be supplied continuously even without using any feeding means for hot air feeding, and clean hot air containing no exhaust gas can be supplied into the glasshouse so that an operator in the glasshouse can be provided with harmless working environments.

Description

Technical Field [0001] The present invention relates to a hot air supplying apparatus,

The present invention relates to a hot air supply device for a greenhouse, and more particularly, to a hot air supply device for a greenhouse which is capable of continuously supplying hot air without using a separate pressure feeding means for feeding hot air, And to provide a warm air supply device for a greenhouse which can provide a harmless work environment to a worker inside the greenhouse.

Generally, agricultural products produced in rural areas, such as pepper, tobacco for mushroom, ginseng, mossam, rice, radish, and garlic, and seafood such as seaweed, kelp, and anchovy, which are produced in fishing villages, If not dried, the value of the product is lost.

Therefore, in the past, the agricultural products or aquatic products were naturally dried using the solar heat, but the natural drying was largely dependent on the drying condition depending on the weather, that is, the weather conditions, and the drying time required for the above- There was a problem that it could not be produced.

Recently, a forced drying method has been adopted so as to be able to easily control the release and shipment amount of dried material and to be capable of mass processing. As a typical example, a plurality of shelves are installed in a greenhouse such as a vinyl house, A method of supplying warm air to the inside of a greenhouse using a warm air supply means such as a boiler is used.

1 is a view showing a conventional warm air supply device for a greenhouse.

As shown in FIG. 1, the conventional warm air supply device for a greenhouse includes a main body having a heating space formed therein, a burner installed inside the main body and heating outside air introduced into the main body to generate hot air, And a hot air supply pipe connected to one side of the formed body and the other side communicating with the inside of the greenhouse to supply warm air generated by the burner to the inside of the greenhouse.

In such a conventional warm air supply device for a greenhouse, when the outside air is introduced into the main body, the outside air is heated by the burner to generate warm air, and the warm air generated by the pressure generated when the outside air is heated and expanded flows through the hot air supply pipe Is supplied to the inside of the greenhouse, and the supplied warm air is circulated in the greenhouse by the convection to dry the dried object.

However, in the conventional warm air supply device for greenhouse, since exhaust gas is contained in the hot air generated by the external air heated directly to the flame of the burner, and the hot air including the exhaust gas is supplied into the greenhouse, the harmful substances contained in the exhaust gas There is a problem that it is adhered to the object to be dried and exhaust gas is present in the work space, which is harmful to workers working inside the greenhouse.

As described above, the conventional warm air supply device for a greenhouse supplies hot air to the interior of the greenhouse by the pressure generated by expansion of the outside air. In order to supply the hot air, There is a problem that the drying efficiency of the drying object is low.

In order to improve the drying efficiency of the object to be dried, a method of forcibly moving the warm air into the greenhouse using a pressurizing means such as a blower is used. However, in order to maintain the internal temperature of the greenhouse at a predetermined temperature, The pressure feeding means for feeding the hot air to be supplied is continuously driven and the power consumption is remarkably increased and the maintenance cost for maintaining the power consumption is remarkably increased.

However, in the conventional greenhouse 100 for drying agricultural and marine products, hot air supplied from the hot air supply pipe 130 is circulated by convection to dry the object to be dried. As the working space inside the greenhouse 100 becomes larger, The circulation of the warm air is not properly performed, so that the temperature inside the greenhouse is partially varied, and there is a problem that the drying efficiency varies depending on the position where the drying object is seated.

Conventionally, in order to prevent the drying efficiency from being lowered due to the temperature deviation, the conventional greenhouse for drying agricultural and marine products is supplied with hot air at a high temperature of about 130 ° C., .

In addition, in the conventional greenhouse for drying agricultural and marine products, the drying object is dried as the warm air is circulated by the convection as described above. In order to prevent the heat of the warm air from being discharged to the outside, Since the drying operation is performed in a state where the air vent formed in the main body is closed and the number of the formation of the complete mechanism is minimized in order to minimize the heat loss, the inside of the greenhouse is always kept moist by the moisture contained in the drying object, There is a problem that the drying efficiency is significantly lowered.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for continuously supplying hot air without using a separate press- To a greenhouse to provide a harmless work environment to a worker inside the greenhouse.

It is a further object of the present invention to provide a method and a device for supplying hot air uniformly to the inside of a greenhouse as a whole so that the drying efficiency can be kept the same regardless of the position where the object to be dried is placed, Which is capable of significantly improving the drying efficiency by allowing the inside air of the greenhouse to be discharged to the outside by the rising air current.

According to an aspect of the present invention, there is provided a warm air supply apparatus for supplying warm air into a greenhouse, the apparatus comprising: a main body having a heating space formed therein; and a burner installed at one side of the main body A compressed air storage portion which is installed outside the main body and stores compressed air therein; a compressed air storage portion having one end connected to the compressed air storage portion and the other end communicated with the interior of the greenhouse, Wherein the burner transforms the compressed air passing through the compressed air supply pipe into hot air by heating one side of the compressed air supply pipe passing through the heating space, One end of which is connected to the compressed air storage portion and the other end is disposed inside the greenhouse, one side of which passes through the heating space of the main body A lateral air warm air supply pipe provided inside the greenhouse in the longitudinal direction of the greenhouse and connected to the compressed air conveying pipe and having a plurality of discharge holes formed along a longitudinal direction on one side thereof, And a rising air flow forming tube installed at a lower side of the inside of the inside, one side of which is connected to one side of the compressed air transfer tube, and the upper side has a plurality of spray holes.

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In addition, it is preferable that the compressed air conveyance pipe is formed so that one side of the compressed air conveyance pipe passing through the heating space is bent a plurality of times.

The boiler may further include an exhaust gas discharge pipe connected to one side of the main body so as to communicate with the heating space at one end and extending in the outer direction of the main body at the other end to exhaust the exhaust gas generated from the heating space to the outside .

According to the present invention, the compressed air supplied to the inside of the greenhouse is heated through the compressed air supply pipe, and the warm air is easily supplied to the inside of the greenhouse by using the expansion force of the compressed air. It is possible to continuously supply warm air even without using the means and to supply a clean warm air not containing exhaust gas to the interior of the greenhouse to provide a harmless working environment to the inside of the greenhouse.

According to the present invention, a lateral warm air supply pipe is disposed in the greenhouse in the longitudinal direction of the greenhouse, and hot air is supplied through a plurality of discharge holes formed in the lateral warm air supply pipe to uniformly supply warm air to the inside of the greenhouse The drying efficiency can be kept the same regardless of the position where the drying object is disposed.

In addition, according to the present invention, a rising air flow forming tube for supplying warm air upward is provided in the lower part of the greenhouse, so that the moisture contained in the drying object is discharged to the outside by the ascending air current.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a conventional warm air supply device for a greenhouse,
2 is a view illustrating a warm air supply device for a greenhouse according to an embodiment of the present invention,
FIG. 3 illustrates the interior of a greenhouse according to an embodiment of the present invention,
4 is a view illustrating an operation of a warm air supply device for a greenhouse according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a view illustrating a warm air supply device for a greenhouse according to an embodiment of the present invention, and FIG. 3 is a view illustrating an interior of a greenhouse according to an embodiment of the present invention.

2 to 3, the warm air supply device 1 for a greenhouse according to an embodiment of the present invention includes a boiler 10, a compressed air storage unit 20, and a compressed air supply pipe 30 .

The boiler 10 includes a fuel supply hopper 11, a main body 12, a burner 13 and an exhaust gas discharge pipe 14, and supplies compressed air passing through a compressed air supply pipe 30 And is heated to generate warm air.

The fuel supply hopper 11 is formed in a funnel shape having a substantially vertical light-narrowing funnel, and serves to supply fuel to the burner 30 so that the fuel flows from the outside and the burner 13 generates a flame.

The main body 12 is formed in a substantially cylindrical shape and has a heating space 12a formed therein for heating one side of the compressed air supply pipe 30 through which one side of the compressed air supply pipe 30 described later passes, do.

The main body 12 serves to provide the heating space 12a of compressed air by the burner 13 and to provide a space for installing the burner 13. [

The burner 13 is installed on the inner side of the main body 12 and generates a flame and heats the compressed air conveyed through the compressed air conveyance pipe 31 to generate warm air. It is obvious to those skilled in the art that a commercially available supply can be purchased and used, and a detailed description thereof will be omitted.

The exhaust gas discharge pipe 14 is connected to the heating space 12a of the main body 12 at one end and extends outward from the main body 12 from one side of the main body 12 to compress the exhaust gas generated in the heating space 12a And discharging it from the air and isolated state to the outside.

The compressed air storage portion 20 is formed in the shape of a substantially cylindrical pressure vessel, and a compressed air storage space for storing compressed air therein is formed. The compressed air storage portion 20 temporarily stores compressed air until the compressed air is supplied into the greenhouse And store it.

One side of the compressed air supply pipe 30 is connected to one side of the compressed air storage unit 20 and the other side is communicated with the inside of the greenhouse O. One side of the compressed air supply pipe 30 passes through the heating space 12a of the main body 12, The compressed air supply pipe 30 is configured to include a compressed air transfer pipe 31 and a lateral warm air supply pipe 32 and an upward airflow forming pipe 33 .

One end of the compressed air transfer pipe 31 is connected to one side of the compressed air storage part 20 and the other end of the compressed air transfer pipe 31 is disposed inside the greenhouse O, (12a), and the compressed air is heated by the burner (13) to generate hot air.

The compressed air transfer pipe 31 is bent in a helical coil shape at a side C passing through the heating space 12a to increase the heat exchange area of the compressed air and the flame provided by the burner 13, So that the heating efficiency of the air is increased.

In addition, it is preferable that the compressed air transfer pipe 31 is provided with an on-off valve 31a in the vicinity of the compressed air storage unit 20 so as to control the supply of compressed air.

The lateral warm air supply pipe 32 is formed in a substantially tubular shape and is disposed inside the greenhouse O along the longitudinal direction of the greenhouse O and has a plurality of discharge holes 32a spaced apart from each other at a predetermined distance .

One side of the lateral warm air supply pipe 32 is connected to one side of the compressed air transfer pipe 31 and supplies hot air to the ground through the above described discharge hole 32a in the horizontal direction, Thereby uniformly supplying warm air to the outdoor unit.

On the other hand, it is preferable that the lateral warm air supply pipe 32 is provided in a multi-stage inside the greenhouse O to supply the warm air to the inside of the greenhouse O more uniformly.

The upward airflow forming tube 33 is installed at a lower one side of the inside of the greenhouse O and one side is connected to one side of the compressed air transfer pipe 31. A plurality of spray holes 33a Spaced apart.

The upward airflow forming tube 33 receives the warm air transferred through the compressed air transfer pipe 31 and blows the supplied warm air through the spray hole 33a to form upward flow in the greenhouse O So that the wet internal air of the greenhouse O and the warm air discharged from the lateral warm air supply pipe 32 are moved upward together.

In other words, the uprising air flow forming pipe 33 continuously blows warm air upward from the bottom surface of the greenhouse O to form a rising airflow, so that water contained in the drying object disposed in the drying rack inside the greenhouse O And a ventilation hole (H) of a greenhouse (O) in which the hot air discharged from the lateral warm air supply pipe (32) is formed on the upper part, so that the drying efficiency of the drying object can be greatly improved.

4 is a view illustrating an operation of the warm air supply device for a greenhouse according to an embodiment of the present invention.

The operation of the warm air supply device 1 according to an embodiment of the present invention having the above-described structure will now be described with reference to FIG.

First, when the open / close valve 31a provided at one side of the compressed air transfer pipe 31 is opened, the compressed air stored in the compressed air storage unit 20 is expanded into the compressed air transfer pipe 31.

The compressed air flowing into the compressed air conveyance pipe 31 travels along the compressed air conveyance pipe 31 and passes through the burner 13 when passing through the compressed air conveyance pipe 31 corresponding to the heating space 12a And the generated hot air is moved along the compressed air conveyance pipe 31 by the expansion force of the compressed air and then flows into the lateral warm air supply pipe 32 and the ascending air flow forming pipe 33.

Here, the warm air introduced into the lateral warm air supply pipe 32 is uniformly supplied to the inside of the greenhouse O through the discharge hole 32a of the multistage warm air supply pipe 32 provided in the multi-stage.

At this time, the hot air flowed into the uprising airflow forming tube 33 is moved along the upward airflow forming tube 33 and is sprayed upward from the bottom surface of the greenhouse O through the plurality of spray holes 33a, Thereby forming an ascending air flow inside.

The ascending air flow formed as described above is moved to the upper part of the greenhouse O. In the process of moving the upward airflow, the upward flow of the upward airflow is transmitted to the upper part of the greenhouse O together with the moisture contained in the object to be dried, And is discharged to the outside through a plurality of vent holes (H) formed on the upper part of the greenhouse (O).

As described above, the warm air supply device 1 for a greenhouse according to an embodiment of the present invention is capable of continuously supplying warm air without using a separate press-feeding means for feeding warm air by the expansion force of compressed air, And can provide a warm air of cleanness inside the greenhouse (O).

In addition, the warm air supply device 1 for a greenhouse according to an embodiment of the present invention can uniformly supply warm air into the greenhouse O and also forms a rising airflow continuously through the rising airflow forming pipe 33, The moisture contained in the drying object is simultaneously discharged through the ventilation hole H of the greenhouse O by the airflow so that the drying efficiency can be greatly improved and the inside of the greenhouse O can be maintained comfortably .

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the appended claims are intended to cover such modifications or changes as fall within the scope of the invention.

1: Greenhouse warm air supply device 10: Boiler
11: fuel supply hopper 12: main body
12a: Heating space 13: Burner
14: Exhaust gas discharge pipe 20: Compressed air storage section
30: Compressed air supply pipe 31: Compressed air supply pipe
31a: opening / closing valve 32: lateral warm air supply pipe
32a: Discharge hole 33: Upward air flow forming tube
33a:

Claims (5)

A warm-air supply device for a greenhouse for supplying warm air to the inside of a greenhouse,
A boiler including a main body having a heating space formed therein and a burner installed at one side of the main body;
A compressed air storage unit installed outside the main body and storing compressed air therein;
A compressed air supply pipe having one end connected to the compressed air reservoir and the other end communicating with the interior of the greenhouse and having one side passing through a heating space of the main body,
The burner heats one side of the compressed air supply pipe passing through the heating space to convert the compressed air passing through the compressed air supply pipe into warm air,
The compressed air supply pipe
A compressed air conveying pipe having one end connected to the compressed air storage portion and the other end disposed inside the greenhouse and having one side passing through the heating space of the main body;
A lateral warm air supply pipe installed inside the greenhouse in the longitudinal direction of the greenhouse and connected to the compressed air transfer pipe and having a plurality of discharge holes formed along a longitudinal direction at one side thereof; And
And a rising air flow forming tube installed on a lower side of the inside of the greenhouse, one side of which is connected to one side of the compressed air conveying pipe, and a plurality of spray holes are formed on an upper side of the greenhouse forming tube.
delete delete The method according to claim 1,
Wherein the compressed air conveyance pipe is formed such that one side of the compressed air conveyance pipe passing through the heating space is bent a plurality of times.
The method according to claim 1,
The boiler further includes an exhaust gas discharge pipe connected to one side of the main body so as to communicate with the heating space at one end and extending toward the outside of the main body at the other end to discharge the exhaust gas generated from the heating space to the outside Wherein the air conditioner comprises:

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