KR101031772B1 - Carbon dioxide supply device using dry ice - Google Patents

Abstract

The present invention relates to a carbon dioxide gas supply device capable of efficiently providing carbon dioxide by vaporizing dry ice in a target space requiring supply of carbon dioxide, such as a vinyl house or a neutralization tank. In particular, it forms a cylindrical lightweight housing in the form of an openable housing, forms a storage box for loading dry ice therein, and connects a gas circulation unit capable of vaporizing dry ice at a required time, thereby providing carbon dioxide gas required for the target space. The present invention relates to a carbon dioxide gas supply device that enables supply of gas at low operating costs.

Light housing, storage box, dry ice, sealing housing, circulation

Description

Carbon dioxide gas supply system using dry ice {CARBON DIOXIDE SUPPLY DEVICE USING DRY ICE}

The present invention relates to a carbon dioxide gas supply device capable of efficiently providing carbon dioxide by vaporizing dry ice in a target space requiring supply of carbon dioxide, such as a vinyl house or a neutralization tank. In particular, it forms a cylindrical lightweight housing in the form of an openable housing, forms a storage box for loading dry ice therein, and connects a gas circulation unit capable of vaporizing dry ice at a required time, thereby requiring carbon dioxide gas in a target space. The present invention relates to a carbon dioxide gas supply device that enables supply of gas at low operating costs.

In general, carbon dioxide (= carbon dioxide) is used in a variety of places, for example, in a greenhouse to grow crops photosynthesis is essential. Therefore, the carbon house must be supplied stably in the vinyl house to grow and commercialize cultivated crops.

Although carbon dioxide is present in the air, the vinyl house is an environment that is blocked from the outside. Therefore, when a large number of crops are photosynthesized, the carbon house gas is not enough to exist in nature. Carbon dioxide is being supplied. To this end, the liquid liquefied carbon dioxide gas is stored in a tank and supplied in an appropriate amount at a necessary time, or a method of generating carbon dioxide by burning fossil fuel.

However, all of these methods cause problems. In the former case, there are many difficulties in the process of injecting or storing the liquid liquefied carbon dioxide into the tank, and a considerable cost is incurred in manufacturing a device for safely storing and supplying the liquefied carbon dioxide gas when necessary. Even in the latter case, the method of generating carbon dioxide by burning fuel is likely to cause hygiene problems to plants and workers inside the plastic house due to the emission of soot and harmful substances.

The present invention relates to a carbon dioxide gas supply device capable of efficiently providing carbon dioxide by evaporating dry ice in a target space requiring supply of carbon dioxide, such as a vinyl house or a neutralization tank, to form a cylindrical lightweight housing in the form of an openable housing. And forming a storage box in which dry ice can be loaded, and connecting a gas circulation unit capable of vaporizing dry ice at a necessary time so that carbon dioxide gas required in the plastic house can be supplied at a low operating cost. To provide a carbon dioxide gas supply device.

In the carbon dioxide gas supply apparatus according to the present invention, in order to supply carbon dioxide gas to the target space by using dry ice, the side plate 31 and the upper plate 32 and the inner space to cover the gas to the upper portion of the support frame 10. Lightweight housing 30 having a portion 33; A storage box (40) having a loading space (42) for receiving one or more dry ice (49) from the inside of the lightweight housing (30) to an upper portion of the support frame (10); And an exhaust pipe 64 positioned at both ends of the circulation pipe 61 in the internal space 33 of the lightweight housing 30 and communicating with the target space, thereby heating the carbon dioxide gas through the circulation pipe 61. And a gas circulation unit 60 which controls the circulation of supplying the carbon dioxide gas generated by evaporating the dry ice 49 from the storage box 40 to the inside of the target space through the exhaust pipe 64.

In the carbon dioxide gas supply apparatus of the present invention, the storage box 40 includes: a communication part 43 communicating carbon dioxide gas at a lower end thereof; A loading part 44 in which a plurality of loading spaces 42 are formed through the one or more diaphragms 41 above the communication part 43; And one or more through-holes 46 formed in the base plate 45 that divides the stacking portion 44 and the communicating portion 43 up and down, to the communicating portion 43 through the circulation pipe 61. It is preferable to comprise so that the heated carbon dioxide gas which has drawn in may rise to the through hole 46 and vaporize the dry ice 49.

In addition, in the carbon dioxide gas supply apparatus of the present invention, one end of the tube is located at the lower end of the inner space 33 of the lightweight housing 30, and is connected to the outside of the gas, and the other side of the storage box 40 is provided. A circulation pipe 61 communicating with the communication part 43; A circulation fan 62 coupled to one side of the circulation tube 61; A heater 63 coupled to the side of the circulation fan 62; And an exhaust pipe 64 coupled to one side of the circulation pipe 61 to be arranged in the target space, and configured to suck carbon dioxide gas present in the internal space 33 through the circulation fan 62 to heat the heater ( 63), and the heated carbon dioxide is supplied to the communicating portion 43 of the lightweight housing 30 to vaporize the dry ice 49 thereon to discharge carbon dioxide gas into the interior of the lightweight housing 30. It is desirable to.

In addition, the carbon dioxide gas supply device of the present invention further comprises a sealing housing 20 to form a predetermined circumference to the upper portion of the support frame 10, the lightweight housing 30 is the water filled in the sealing housing 20 It is preferable that the side plate 31, the top plate 32, and the inner space 33 are formed so as to completely cover the body in the state in which only the lower part is opened so that the end of the side plate 31 is locked to the 21.

In addition, in the carbon dioxide gas supply apparatus of the present invention, the communicating portion 43 is provided with a gap rib plate 75 that forms a gap in the vertical direction, and a communication hole 76 is formed in the gap rib plate 75 to dry ice ( It is preferable to be configured to free the movement of the carbon dioxide gas while supporting 49).

In addition, the carbon dioxide gas supplying apparatus of the present invention is attached to the controller 81 for controlling the output of the heater 63 and the rotation speed of the circulation fan 62 and one side of the circulation tube 61 of the gas circulation unit 60. Temperature sensor 82 for measuring the carbon dioxide gas temperature in the circulation pipe 61, carbon dioxide gas concentration sensor 83 for measuring the concentration of carbon dioxide gas in the target space, or PH sensor 84 for measuring the pH value of the target space. It is preferable to further include a; control system 80 having a).

In the carbon dioxide gas supplying apparatus of the present invention, the circulation fan 62 and the heater 63 are installed at a relatively high position compared to the exhaust pipe 64 so that the vaporized carbon dioxide gas is downward and the circulation fan 62 and the heater 63 are disposed. It is desirable to prevent freezing).

In addition, in the carbon dioxide gas supply apparatus of the present invention, a heat insulating layer 37 is formed on the inner surface of the lightweight housing 30 to block the movement of temperature, and a separate heat insulating bottom is provided between the support frame 10 and the storage box 40. It is preferable to form (17) so as to block the movement of temperature.

According to the carbon dioxide gas supply apparatus of the present invention, the carbon dioxide gas can be supplied to the vinyl house at a lower cost, so that the related cost can be reduced, thereby providing a competitive advantage in selling goods.

In addition, according to the carbon dioxide gas supply apparatus of the present invention, there is an advantage that the maintenance of the system is easy because the user can easily replace or remount the dry ice of heavy weight.

In addition, according to the carbon dioxide gas supply apparatus of the present invention, the structure of the device is relatively simple and the parts required for manufacturing the product is relatively inexpensive, there is an advantage that the manufacturing cost can be lowered.

The present invention relates to an efficient configuration of a carbon dioxide gas supply device for providing carbon dioxide by vaporizing dry ice, the configuration and operation thereof will be described in detail with reference to [1] to [4]. In the present specification, for convenience of description, a vinyl house is described as a target space.

As shown in FIG. 1, a sealing housing 20 having a cross section having a “c” shape to form a circumference is provided to an upper portion of the support frame 10, and water 21 filled in the sealing housing 20 is provided. ) Is provided with a light housing (30) consisting of a side plate (31), an upper plate (32), and an inner space (33) so as to cover the entire surface with only the lower portion of the side plate (31) being opened to lock the end of the side plate (31). An upper box of the inner support frame 10 of the lightweight housing 30 has a rectangular plane and a storage box 40 having a loading space 42 to stack a plurality of dry ice 49 through the diaphragm 41. There is this.

In addition, the end of the circulation pipe 61 is inserted into the inner space portion 33 of the lightweight housing 30, accommodates the exhaust pipe 64 in communication with the interior of the vinyl house 90 to rotate the carbon dioxide gas, 90) there is a gas circulation section 60 that controls the circulation to be fed into the interior. Therefore, by combining them, the dry ice 49 contained in the storage box 40 is vaporized, and saturated carbon dioxide is supplied into the vinyl house 90 only when necessary, and the supplied high concentration carbon dioxide is a separate large-capacity self. It is supplied uniformly into the plastic house by a circulation fan to promote the photosynthetic action of the crop. The user may open the lightweight housing 30 as a whole, and at this time, the dry ice 49 may be replaced.

That is, in the present invention, in supplying carbon dioxide gas required for photosynthesis to the inside of the vinyl house 90, a special tank is not required to provide a high-pressure liquefied gas, and 100% of the work is not required to burn a separate fuel. It adopts a simple loading method of dry ice, a solid mass of carbon dioxide. In pursuit of this method, the present invention has an advantage that the manufacturing cost is low, the cost input for the maintenance is low, and no pollutants are emitted. Therefore, in order to explain the features of the present invention, a problem of a method of supplying carbon dioxide gas into a vinyl house by using liquefied carbon dioxide of the prior art will be briefly described.

Conventional equipment that stores carbon dioxide in a high pressure liquefied state in a tank and vaporizes it to a plastic house, even though it is small, has an installation cost of about 35 million won and a durability of about 8 years. If so, the depreciation value of the conventional liquefied carbon dioxide supplying device is 4,320,000 won per year, the interest cost (financial cost) for the installation of the equipment is 1,380,000 won, and 7 tons of liquefied carbon dioxide, which is usually used in one year of plastic house, The price is about 1.75 million won (that is, 250,000 won per ton).

As a result, the carbon dioxide gas supplying device according to the prior art costs 6 million won a year to maintain the liquefied carbon dioxide gas of 1,750,000 won a year, and accordingly, the total cost of using 1 ton of liquefied carbonate reaches 1.1 million won. . On the other hand, the carbon dioxide gas supply device of the present invention to supply carbonic acid gas by vaporizing the solidified dry ice, although the price of dry ice is relatively expensive compared to liquefied carbonic acid gas, the installation cost of the apparatus is only a few million won, The monthly input costs can be greatly reduced.

The configuration and operation of the present invention will be described in detail. In the present invention, as shown in FIG. 1, only the lower end of the lightweight housing 30 having an open shape is coupled in such a manner as to cover the gas as a whole. In this case, the lightweight housing 30 may be manufactured in various shapes, but may be a circular cross section as shown, or may be manufactured in a polygonal shape such as a square or a pentagon. The lightweight housing 30 is a very simple form consisting of the side plate 31 and the upper plate 32 and the interior space 33, the lightweight housing 30 is covered by the upper portion of the body, such as simply covering the cap coupling The way of doing is preferable.

Looking at the form of the coupling in detail, as shown in [FIG. 1], the body is mounted in the storage box 40, as installed on the upper portion of the support frame 10, and fastened in such a way that a plurality of dry ice 49 is loaded therein. do. In order to prevent the dry ice 49 from being vaporized as it is in the air, the lightweight housing 30 covers the upper portion of the storage box 40, and is preferably fastened in such a manner as to completely cover the storage box 40. At this time, the upper portion of the support frame 10 is coupled to the sealing housing 20 having a cross-section of the "c" shape that is laid in the same shape as the cross-section of the lightweight housing 30. And inside it is filled with water.

Therefore, the end of the side plate 31 of the lightweight housing 30 of the present invention is inserted into the sealing housing 20 of the "C" cross-sectional shape as if through the water side 31 and the sealing housing of the lightweight housing 30 ( 20) is the same as sealing. The first reason for the sealing treatment with the water filled in the sealing housing 20 is to facilitate the coupling and disassembly of the lightweight housing 30, for this purpose, the material of the lightweight housing 30 is made of a synthetic resin that weighs less It is desirable to utilize. The second reason is to prevent carbon dioxide gas formed in the inner space part 33 of the lightweight housing 30 from escaping to the outside, and to prevent outside air from penetrating into the interior of the lightweight housing 30. The third reason is to allow the lightweight housing 30 to be released automatically when the pressure is formed in the inner space 33 to relieve the pressure.

As such, the support frame 10 of the flat form is installed, the storage box 40 loaded with dry ice 49 is mounted on the upper portion, and the lightweight housing 30 is overlapped and covered thereon, The sealing housing 20 is filled with water and is configured in such a manner that the end of the side plate 31 of the lightweight housing 30 is immersed in the water. A gas circulation unit 60 is installed in the storage box 40 and the space part 33 to vaporize the dry ice 49 in a solid form so as to supply carbon dioxide gas only when necessary inside the plastic house.

With reference to FIG. 1, the manner in which the carbon dioxide gas supplying device of the present invention operates will be briefly described. The gas circulation unit 60 employed in the present invention has a structure capable of circulating air. That is, one side is in communication with the internal space portion 33 of the lightweight housing 30, the other side is branched, but one side is arranged to return to the storage box 40 again, the other branch pipe is a plastic house 90 It communicates with the interior of the building to supply carbon dioxide. The internal carbon dioxide of the lightweight housing 30 is sucked through the operating means such as the circulation fan 62, and the sucked carbon dioxide is changed to be heated by a separate means. The carbon dioxide heated in this way is vaporized again to supply carbon to the inside of the lightweight housing 30, more specifically, the lower end of the storage box 40 to vaporize the dry ice 49 loaded in the storage box to generate carbon dioxide gas.

At this time, if the internal pressure of the lightweight housing 30 is increased while repeating such a recirculating action, the pressure is also increased inside the circulation pipe 61 of the gas circulation unit 60. In addition, since carbon dioxide gas is heavier than air, saturated air may be downward to further increase the pressure inside the circulation pipe 61. In this case, when the exhaust pipe 64 branched from the circulation pipe 61 is opened, the carbon dioxide gas is ejected through the exhaust pipe 64 to enter the interior of the vinyl house 90 to help photosynthesis of the crop.

One advantageous feature of the present invention compared to the conventional carbon dioxide gas supply device is that the lightweight housing 30 can be opened as a whole. In other words, rather than dismantling the cover off the top of the body, it can be removed in such a way that the one-piece housing combined with the top plate and the side plate 31 is completely lifted off. Dry ice 49 is heavy in weight and bulky. Therefore, there is a possibility that a worker has a lot of difficulties in carrying the dry ice 49 alone and loading it inside the storage box 40. In order to solve this problem, the present invention manufactures a housing that is peeled up to the side plate 31 and specifically combines the light housing 30 and the support frame 10 in a manner that is superimposed by gravity rather than coupling in a manner of fastening. will be.

The operation of the carbon dioxide gas supply device of the present invention will be described in more detail.

Both inner surfaces of the lightweight housing 30 preferably form a heat insulation layer 37 to block the movement of temperature. As shown in FIG. 1, the lightweight housing 30 is made of a synthetic resin material which is a fairly light material so that the user can open it as a whole. In addition, the inner circumferential surface is applied or coated with a heat insulating layer 37, it is also possible to bond such a coating layer. The reason for forming the heat insulation layer 37 is that dry ice 49 in the present invention maintains a considerable low temperature, so the inside and outside of the lightweight housing 30 are likely to have a large temperature difference. In this case, the heat-insulating layer 37 is formed inside the lightweight housing 30 so that the dry ice 49 is not vaporized at random by the operator's intended time and is not vaporized randomly through heat exchange.

On the other hand, it is desirable to form a separate heat insulating bottom 17 between the support frame 10 and the storage box 40 to block the movement of temperature. That is, the heat insulating bottom 17 is formed between the support frame 10 and the storage box 40 for the same reason as the heat insulating layer 37 is formed in the lightweight housing 30.

For photosynthesis of the cultivated crop, it is preferable that carbon dioxide is introduced into the plastic house 90 only at a suitable time. Since photosynthesis requires carbon dioxide but also sunlight, it is preferable that carbon dioxide gas be discharged from the carbon dioxide gas supply device at night time without sunlight.

In more detail, in the carbon dioxide gas supplying apparatus of the present invention, during the evening time without sunlight, there is a possibility of experiencing a special temperature change at a time when the gas circulation unit 60 is not operated. That is, when the internal temperature is increased and a large amount of carbon dioxide is generated in the dry ice 49 and the pressure therein increases, there is a possibility that carbon dioxide gas is unnecessarily supplied into the vinyl house 90 through the exhaust pipe 64. . The supply of such carbon dioxide is virtually no help to grow cultivated crops, only dry ice is consumed to increase the cost.

In order to eliminate this problem, in addition to the consideration of forming a separate insulating layer 37 in the interior of the lightweight housing 30, as described above, a separate insulating bottom between the support frame 10 and the storage box 40 ( 17) to control the phenomenon that the dry ice 49 is vaporized according to the internal temperature as much as possible.

And the configuration of the storage box 40 according to the present invention will be described in detail through [2] and [3]. The carbon dioxide gas communication portion 43 of the circular cross section at the lower end, the upper portion is opened to the upper communication portion 43, four loading spaces 42 are formed through the four diaphragm 41, the quadrilateral There is a loading part 44 forming an outer surface of the cross section, and a plurality of through holes 46 are provided in the base plate 45 that divides the loading part 44 and the communication part 43 in the vertical direction. Therefore, these are combined so that the heated carbon dioxide gas entering the communication portion 43 rises to the through hole 46 to vaporize the dry ice 49.

The storage box 40 is largely divided into a lower communication part 43 and an upper loading part 44, and the physical part is a base plate 45. The communicating portion 43 maintains a circular cross section in a somewhat wider state than the width of the loading portion 44, and the loading portion 44 integrally formed thereon is illustrated in quadrangular shape. The stacking unit 44 is formed of four spaces using the diaphragm 41, and a plurality of dry ice 49 is sequentially stacked in the stacking space 42. 3 shows dry ice 49 stacked in three layers in each loading space 42, but the present invention is not limited thereto. In the gas circulation unit 60, the carbon dioxide gas sucked from the upper portion of the communication unit 43 is directly heated while moving to the circulation tube 61, and is then supplied back into the communication unit 43 at the lower end. The heated carbon dioxide then vaporizes the dry ice 49 further to form more carbon dioxide gas.

The carbon dioxide will be downward when vaporized because it is a heavier gas than air, and the heated carbon dioxide will continue to be supplied. The reason why the heated carbon dioxide gas is not supplied from the upper portion but supplied through the lower communicating portion 43 to rise while passing through the dry ice 49 is to maintain the consistency of the control. If the heated carbonic acid gas is supplied from above, the upper portion of the dry ice 49 is vaporized and its height is lowered, so that the heated carbonic acid gas does not properly touch the dry ice 49, thereby precisely controlling the vaporization. Because I do not lose.

In order to further emphasize such a function, in the present invention, the communication portion 43 of the holder 40 is provided with a gap rib plate 75 that forms a gap in the vertical direction, and the communication hole 76 is formed in the gap rib plate 75. ) To support the dry ice 49 to free the movement of carbon dioxide gas.

That is, the spaced rib plate 75 that vertically crosses the communication part 43 so that the heated carbon dioxide gas is supplied to the lower communication part 43 of the storage box 40 and is evenly raised to the loading part 44. And a plurality of communication holes 76 are formed in the gap rib plate 75. Therefore, the heating carbon dioxide injected into the communication hole 76 is able to ascend to the upper loading part 44 in a state spread evenly in the communication part 43. And the gap rib plate 75 supports the heavy dry ice 49, it can also perform the role of the support to provide the advantage of improving the durability.

In the present invention, a gas gas circulation unit 60 for operating the carbon dioxide gas supply device will be described in detail with reference to FIG. 1. First, the circulation tube 61 is one end of the tube is located at the lower end of the inner space portion 33 of the lightweight housing 30 is connected to the outside of the body and the other side communicates with the communication portion 43 of the storage box (40). The circulation fan 62 is coupled to one side of the circulation tube 61, and the electric heater 63 is coupled to the side of the circulation fan 62. Instead of the electric heater 63, various types of heating means may be used. In addition, the exhaust pipe 64 is coupled to one side of the circulation pipe 61 is arranged inside the vinyl house (90).

These components combine to suck the carbon dioxide gas present in the space portion 33 through the circulation fan 62 and heat it with the electric heater 63, and the heated carbon dioxide gas communicates with the lightweight housing 30. By supplying 43 to the loaded dry ice 49, the carbon dioxide gas is supplied into the vinyl house 90 by discharging a large amount of carbon dioxide into the light housing 30. The control system 80 controls all such operations.

That is, the gas circulation unit 60 is for supplying carbon dioxide gas generated by evaporating the dry ice 49 inside the lightweight housing 30 to the inside of the vinyl house 90. In the arrangement form, one end of the circulation tube 61 is installed at the lower end of the lightweight housing 30 as shown in FIG. That is, it is located directly on the top of the communication portion 43 of the storage box (40). In addition, the circulation pipe 61 extends in length so as to communicate with the circulation fan 62 and the electric heater 63, and communicates with the communication part 43 located at the bottom of the inner storage box 40 of the lightweight housing 30 again. The other end is installed.

Looking at the movement path of the carbon dioxide gas in the carbon dioxide gas supply apparatus of the present invention. That is, when the gas circulation unit 60 starts to operate, the internal circulation gas of the light housing 30 may be sucked through the circulation pipe 61 having an end thereof directly above the storage box 40 inside the light housing 30. do. Suction is induced through the connected circulation fan 62, and the carbon dioxide gas sucked in this way is heated in the electric heater 63 while rotating in the circulation pipe 61. The carbon dioxide heated in this way is re-injected into the communication part 43 of the storage box 40, that is, the lower portion of the lightweight housing 30.

Then, the carbon dioxide gas, which is heated in the electric heater 63 and is relatively hot, rises through the through hole 46 of the bottom plate 45 in the state of being spread through the communication part 43 to the loading part 44. By vaporizing the dry ice 49 loaded in the loading section 44, carbon dioxide is released. Since carbon dioxide is heavier than air, the carbon dioxide is discharged to the upper portion of the loading part 44 and is generally kept downward and saturated in the light housing 30. The dry ice 49, which is a solid, is changed into gas and the internal pressure is increased. As a result of moving in the exhaust pipe (64) communicated from one side of the circulation pipe (61) is put into the vinyl house (90) side.

Here, since carbon dioxide is heavier than air, it will generally be downward after vaporizing, so that one end of the circulation pipe 61 is located directly above the communicating portion 43, that is, at the lower end of the lightweight housing 30. It is preferable. However, as the interior of the lightweight housing 30 is saturated with carbon dioxide, the vertical position of the end of the circulation tube 61 will gradually become meaningless, so even if disposed at any position, the operation of the present invention may not have a significant effect. .

The operation of the present invention described above can be continued for as long as desired by the operator at a convenient time, thereby facilitating control thereof. That is, the gas circulation unit 60 may be automatically controlled through the control system 80.

In order to configure the control system 80, the controller 81 for controlling the rotation speed of the electric heater 63 and the circulation fan 62 and the circulation pipe 61 on one side as shown in FIGS. A temperature sensor 82 is attached to measure the carbon dioxide gas temperature in the circulation pipe 61 and a carbon dioxide gas concentration sensor 83 for measuring the carbon dioxide gas concentration in the vinyl house 90. In addition, when used as a neutralization gas of water or wastewater, a PH sensor 84 for measuring the pH value of water is provided. Therefore, when they are combined, the controller 81 stops the operation of the electric heater 63 when the temperature rises excessively, and the controller 81 causes the circulation fan 62 and the electric heater ( It is operated by controlling the operation of 63).

The control system 80 of the present invention controls the flow of carbon dioxide gas by controlling the circulation fan 62 and the electric heater 63. That is, when carbon dioxide is needed, the circulation fan 62 and the electric heater 63 are selectively operated, and the carbon dioxide gas inside the lightweight housing 30 is sucked from one end of the circulation pipe 61 and heated again. By supplying the communication part 43 of the storage box 40, a larger amount of carbon dioxide gas is generated, and this is again supplied to the inside of the vinyl house through the exhaust pipe 64.

All these operations are controlled through various sensors, namely, temperature sensor 82, concentration sensor 83, PH sensor 84. The temperature sensor 82 is preferably installed before the electric heater 63 on one side of the circulation tube 61. If it is determined that the temperature of the carbon dioxide gas sucked through the temperature sensor 82 is too high, it is preferable to stop the electric heater 63 to protect the entire facility from fire.

It is preferable to install the PH sensor 84 and the carbon dioxide concentration sensor 83 in the plastic house 90 so that the controller 81 reflects the measurement result. That is, if the carbon dioxide concentration is measured too high, the operation of the circulation fan 62 and the electric heater 63 is stopped, and if the opposite measurement value is obtained, the operation is controlled in the direction of expanding the operation.

On the other hand, the circulation fan 62 and the electric heater 63 are installed at a relatively high position relative to the exhaust pipe 64 of the gas circulation unit 60, so that carbon dioxide, which is heavier and colder than air, is lowered and the circulation fan 62 and It is desirable to eliminate the possibility of freezing the electric heater 63 at source.

In other words, carbon dioxide is heavier than air and is significantly colder. If the gas circulation unit 60 is operated to move carbon dioxide gas into the circulation pipe 61 and the exhaust pipe 64, there is no problem, but there may be a big problem in the evening or when the operation is unnecessary. Even when the gas circulation unit 60 is not operated, the dry ice 49 discharges the low temperature carbon dioxide gas, and the discharged carbon dioxide gas is lowered to the lower position in the circulation tube 60. Therefore, if the circulation fan 62 and the electric heater 63 are installed at a lower position than the exhaust pipe 64, the low temperature carbon dioxide gas is discharged to the outside to freeze the electric heater 63 and the circulation fan 62 at the lower end. In addition, the natural loss of dry ice is increased. In consideration of these matters, the circulation fan 62 and the electric heater 63 are preferably installed at a higher position than the exhaust pipe 64.

1 is a cross-sectional view showing an overall carbon dioxide gas supply apparatus of the present invention,

2 is a view showing a holder of the supply apparatus of the present invention,

3 is an exploded view illustrating the supply apparatus of the present invention;

4 is a block diagram showing a supply apparatus control method of the present invention.

<Brief description of the major symbols in the drawings>

10; Support frame 20; Sealing housing

21; Water 30; Lightweight housing

31; Shroud 32; Tops

33; Space 40; glove compartment

41; Diaphragm 42; Loading space

43; Communication section 44; Loading section

45; Base 46; Through hole

49; Dry ice 60; Circulation

61; Circulation tube 62; Circulation fan

63; Electric heater 64; vent pipe

75; Spacing rib plate 76; Communicator

80; Control system 81; controller

82; Temperature sensor 83; Concentration sensor

84; PH sensor 90; plastic house

Claims (9)

An apparatus for supplying carbon dioxide gas to a target space using dry ice, A light housing 30 having a side plate 31, an upper plate 32, and an inner space 33 to cover the gas to the top of the support frame 10; A storage box (40) having a loading space (42) for receiving one or more dry ice (49) to an upper portion of the support frame (10) in the interior of the lightweight housing (30); And Both ends of the circulation pipe 61 are located in the inner space 33 of the lightweight housing 30 and are configured to accommodate the exhaust pipe 64 communicating with the target space, so that carbon dioxide gas is supplied through the circulation pipe 61. A gas circulation unit 60 for heating and circulating and controlling a circulation of supplying carbon dioxide gas generated by evaporation of the dry ice 49 in the holder 40 into the target space through the exhaust pipe 64; Carbon dioxide gas supply device configured to include. The method according to claim 1, The holder 40 is, Communicating portion 43 for communicating carbon dioxide to the bottom; A loading part 44 in which a plurality of loading spaces 42 are formed through at least one diaphragm 41 above the communication part 43; And One or more through-holes 46 formed in the base plate 45 for partitioning the stacking portion 44 and the communicating portion 43 up and down; It is configured to include, the carbonic acid characterized in that the heated carbon dioxide introduced into the communication portion 43 through the circulation pipe 61 to the through-hole 46 while vaporizing the dry ice 49 Gas supply. The method according to claim 2, The gas circulation unit 60, One end of the tube is located at the lower end of the inner space portion 33 of the lightweight housing 30 is connected to the outside of the body and the other side is in communication with the communicating portion 43 of the storage box (40); A circulation fan 62 coupled to one side of the circulation tube 61; A heater 63 coupled to the side of the circulation fan 62; And An exhaust pipe 64 coupled to one side of the circulation pipe 61 and arranged in a target space; Consists of including, The carbon dioxide gas existing in the internal space part 33 is sucked through the circulation fan 62 and heated by the heater 63, and the heated carbon dioxide gas is connected to the communication part 43 of the lightweight housing 30. Carbon dioxide gas supply device characterized in that the carbon dioxide gas is discharged into the interior of the light housing by vaporizing the dry ice (49) of the upper portion. The method of claim 3, The carbon dioxide gas supply device further comprises a sealing housing 20 forming a predetermined circumference to the upper portion of the support frame 10, The lightweight housing 30 has a side plate 31 and a top plate 32 so as to completely cover the gas in a state in which only a lower portion thereof is opened so that the end of the side plate 31 is locked in the water 21 filled in the sealing housing 20. And carbon dioxide gas supply device comprising an inner space (33). The method according to claim 4, In the communicating portion 43, a gap rib plate 75 is formed to form a gap in the vertical direction, and a communication hole 76 is formed in the gap rib plate 75 to support the dry ice 49 while the carbon dioxide gas is supported. Carbon dioxide gas supply apparatus characterized in that the movement of the free. The method according to claim 5. The carbon dioxide gas supply device, The controller 81 which controls the rotation speed of the heater 63 and the circulation fan 62 and the carbon dioxide gas temperature inside the circulation tube 61 are attached to one side of the circulation tube 61 of the gas circulation unit 60. A control system 80 having a temperature sensor 82 for measuring a carbon dioxide concentration sensor 83 for measuring a carbon dioxide gas concentration in a target space; Carbon dioxide gas supply device further comprises. The method according to claim 5. The carbon dioxide gas supply device, The controller 81 which controls the rotation speed of the heater 63 and the circulation fan 62 and the carbon dioxide gas temperature inside the circulation tube 61 are attached to one side of the circulation tube 61 of the gas circulation unit 60. A control system 80 having a temperature sensor 82 for measuring the pH sensor and a PH sensor 84 for measuring the PH value of the target space; Carbon dioxide gas supply device further comprises. The method according to claim 6 or 7, The circulation fan 62 and the heater 63 are installed at a higher position than the exhaust pipe 64 to prevent vaporized carbonated gas from flowing downward to freeze the circulation fan 62 and the heater 63 and to dry. Carbon dioxide gas supply device characterized in that to minimize the natural loss of ice. The method according to claim 8, The inner surface of the lightweight housing 30 to form a heat insulating layer 37 to block the movement of temperature, Carbon dioxide gas supply device, characterized in that for blocking the movement of temperature by forming a separate insulating bottom 17 between the support frame 10 and the storage box (40).

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