KR200353286Y1 - A Dryice Manufacture Aapparatus - Google Patents

Abstract

The present invention relates to a dry ice manufacturing apparatus capable of continuously manufacturing dry ice by preventing liquid snow from being frozen on the inner surface of the snow chamber while simultaneously injecting liquid carbon dioxide into the snow chamber. A valve 10 for adjusting a flow rate of the liquid carbon dioxide injected into one side thereof; As the valve 10 is opened and closed, some of the liquid carbon dioxide supplied into the snow is generated as snow, and the other is discharged through the gas outlet 22 coupled to the upper surface to discharge the gas generated by vaporization. A snow chamber unit 20; Hydraulic piston unit 30 to produce a dry ice chopped to fall by its own weight as the snow generated in the snow chamber 20 is stacked; An oil pressure generating unit (40) comprising an oil pump (P) and an oil tank (T) for supplying oil according to the driving of the motor (M) for the operation of the hydraulic piston unit (30); According to the driving of the hydraulic generator 40, a plurality of discharge grooves 50 having a plurality of forming grooves 52 having the same size at regular intervals such that the dry ice compacted by the hydraulic piston unit 30 is discharged in a predetermined size and the same shape. In the dry ice manufacturing apparatus consisting of), is wound in a spiral around the outer periphery of the snow chamber 20, one end thereof is connected to one end of the oil pump (P) of the hydraulic generating unit 40, the other end is oil A heat medium circulation pipe 60 connected to one side of the tank T to circulate the heat medium therein; The heat medium circulation pipe 20 is formed of a cover part 70 which receives a portion of the heat medium circulation pipe 20 spirally wound around the outer periphery of the snow chamber part 40 to prevent heat emission to the outside by receiving the inside thereof. By circulating the oil at room temperature into the heat medium circulation pipe wound around the outer periphery of the snow chamber part, snow is accumulated on the inner surface of the snow chamber part, thereby preventing freezing phenomenon, thereby producing continuous dry ice. .

Description

Dry ice manufacturing apparatus {A Dryice Manufacture Aapparatus}

The present invention relates to an apparatus for manufacturing dry ice, and more particularly, to prevent dry snow from being frozen on the inner surface of the snow chamber while the liquid carbon dioxide is injected into the snow chamber. It relates to a dry ice manufacturing apparatus that can be produced.

In general, dry ice (Dry ice) is mainly used to cool the food because it evaporates at room temperature and does not leave any residue.

The dry ice manufacturing apparatus as described above will be described with reference to FIG. 1.

General dry ice manufacturing apparatus, the valve 100 for adjusting the flow rate of the liquid carbon dioxide injected into one side; As the valve opens and closes, some of the liquid carbon dioxide supplied into the snow is generated as snow, and the other part is discharged through the gas outlet 220 coupled to the upper surface to discharge the gas generated by vaporization. 200; A hydraulic piston unit 300 which generates dry ice by compacting falling by its own weight as dry ice generated inside the snow chamber 200 is stacked; An oil pressure generating unit 400 including an oil pump 440 and an oil tank 460 for supplying oil according to the operation of the motor 420 for the operation of the hydraulic piston unit 300; According to the driving of the hydraulic generator 400, a plurality of discharge grooves 500 having a plurality of forming grooves 520 having the same size at a predetermined interval so that the dry ice compacted by the hydraulic piston unit 300 is discharged in a predetermined size and the same shape. )

The dry ice manufacturing apparatus first connects the valve 100 to a storage tank (not shown) in which liquid carbon dioxide gas is stored.

Then, when the valve 100 is opened and closed, the liquid carbon dioxide stored in the storage tank is injected into the valve 100, and the injected liquid carbon dioxide is introduced into the snow chamber part 200 through the valve 100. Supplied.

The snow chamber part 200 has a hollow portion formed therein, and a gas outlet 220 having a tubular shape through which gas is discharged is coupled to an upper surface of the snow chamber part 200.

Then, 50% of the liquid carbon dioxide gas supplied into the snow chamber part 2000 is generated as snow, and accumulated from the bottom of the snow chamber part 200, and the temperature inside the snow chamber part is -60 ° C.

At this time, the remaining 50% of the liquid carbon dioxide except 50% generated by snow is vaporized in the snow chamber 200 to generate a gas, the gas is a gas coupled to the upper surface of the snow chamber 200 It is discharged through the outlet 220.

On the other hand, the snow accumulated from the inner bottom of the snow chamber unit 200 is dropped by its own weight, the circulation is accumulated while the snow is generated again by the liquid carbon dioxide continuously supplied to the snow chamber unit 200 again Is repeated.

Then, when the snow falls by its own weight, the snow is located inside the hydraulic piston part 300 which is located at the lower end of the snow chamber part 200, and the hydraulic piston part 200 is connected to the hydraulic pressure generating part 400. The snow that is driven by the falling down by the self-weight is pushed toward the discharge port 500, the snow is continuously piled up to continue to be pushed toward the discharge port 500 is compacted to produce a dry ice and is discharged through the discharge port 500 at the same time .

The oil pressure generating unit 400 is an oil tank 460 positioned at one side of the oil pump 440 and the oil pump 440 located at one side of the motor 420 and the motor 420. As the 420 is driven, the oil pump 440 is operated, and the oil of the oil tank 460 is transferred to the hydraulic piston unit 220 by the hydraulic pressure generated according to the operation of the oil pump 440 to the hydraulic piston. The driving unit 300 is driven.

In addition, the dry ice having the same size and shape in the discharge hole 500 and discharged in a compacted state through a plurality of forming grooves 520 formed at predetermined intervals is discharged in the same size and shape as the forming groove 520. In addition, the discharged dry ice is cut into a predetermined size and used.

At this time, the forming groove 520 may be formed in a variety of circles, squares, hexagons, octagons, etc. Accordingly, dry ice may also be formed in various shapes.

On the other hand, in the dry ice manufacturing apparatus as described above, the snow is solidified on the inner surface of the snow chamber portion in the process of generating the liquid carbon dioxide gas supplied into the snow chamber portion into the snow, that is, the snow is stuck in the frozen state If the fall does not fall due to its own weight, continuous dry ice production is not made, and there is an uncomfortable problem of removing snow attached to the inner surface of the snow chamber part one by one.

In order to solve the above problems, the present invention prevents the liquid carbon dioxide gas supplied into the snow chamber part from solidifying on the inner surface of the snow part chamber part in the process of generating snow and not falling by its own weight. It is an object of the present invention to provide a dry ice manufacturing apparatus in which the heat medium at room temperature is circulated in the outer circumference of the snow chamber to exchange heat.

1 is a side view showing a dry ice manufacturing apparatus according to the prior art.

Figure 2 is a side view showing a dry ice manufacturing apparatus according to the present invention.

3 is a cross-sectional view showing a heat medium circulation tube and a cover of the present invention.

Explanation of symbols on the main parts of the drawings

10: valve 20: snow chamber portion

22: gas discharge pipe 30: hydraulic piston portion

40: hydraulic pressure generating unit 50: discharge port

52: forming groove 60: heat medium circulation tube

70: cover part M: motor

P: oil pump T: oil tank

The present invention is a valve for controlling the flow rate of the liquid carbon dioxide gas injected into one side in order to achieve the above object; A snow chamber part of the liquid carbon dioxide gas supplied into the snow according to the opening and closing of the valve, the snow chamber part being discharged through a gas outlet coupled to the upper surface to discharge the gas generated by vaporization; A hydraulic piston unit which generates dry ice by compacting the falling of the snow generated inside the snow chamber unit by its own weight; A hydraulic generator comprising an oil pump and an oil tank for supplying oil according to the driving of the motor for the operation of the hydraulic piston unit; In the dry ice manufacturing apparatus comprising a plurality of discharge grooves formed with a plurality of forming grooves having the same size at regular intervals so that the dry ice compacted by the hydraulic piston unit is discharged in a predetermined size and the same shape according to the driving of the hydraulic generating unit, the snow chamber A heat medium circulation pipe wound spirally around the outer periphery of the part, one end of which is connected to one side of the oil pump of the hydraulic generator, and the other end of which is connected to one side of the oil tank; It provides a dry ice manufacturing apparatus consisting of a cover portion for receiving the heat medium circulation tube portion spirally wound around the outer periphery of the snow chamber portion of the heat medium circulation tube to prevent heat discharge to the outside.

(Example)

With reference to the accompanying drawings, the dry ice manufacturing apparatus according to the present invention will be described in detail.

1 is a side view showing a dry ice manufacturing apparatus according to the related art, FIG. 2 is a side view showing a dry ice manufacturing apparatus according to the present invention, and FIG. 3 is a heat medium circulation tube and a cover of the present invention. It is sectional drawing shown.

The configuration of the dry ice manufacturing apparatus according to the present invention, the valve 10 for controlling the flow rate of the liquid carbon dioxide gas injected into one side, and part of the liquid carbon dioxide gas supplied into the inside according to the opening and closing of the valve 10 Is generated as a snow, and the other part of the snow chamber 20 is discharged through the gas outlet 22 coupled to the upper surface to discharge the gas generated by the vaporization, and generated inside the snow chamber 20 As the snow is accumulated, the hydraulic piston unit 30 which is formed by the dry ice by compacting falling by its own weight, the oil supplying the oil according to the driving of the motor M for the operation of the hydraulic piston unit 30 The hydraulic ice generator 40 composed of the pump P and the oil tank T and the dry ice compacted by the hydraulic piston portion 30 according to the driving of the hydraulic oil generator 40 have the same size and shape. Discharged In the dry ice manufacturing apparatus consisting of a plurality of outlets 50 formed with a plurality of forming grooves 52 having the same size as the lock,

Spirally wound around the outer periphery of the snow chamber 20, one end thereof is connected to one side of the oil pump (P) of the hydraulic generator 40, the other end is connected to one side of the oil tank (T) The heat medium circulation pipe 60 through which the heat medium is circulated is formed.

In addition, the cover portion 70 for receiving a portion of the heat medium circulation pipe 60 spirally wound around the outer periphery of the snow chamber 20 of the heat medium circulation pipe 60 to prevent heat dissipation to the outside. Is formed.

On the other hand, before explaining the dry ice manufacturing apparatus according to the present invention as described above will be described with reference to Figure 2 attached to the description of the conventional dry ice apparatus.

In the conventional dry ice manufacturing apparatus, first, a storage tank (not shown) in which liquid carbon dioxide is stored is connected to the valve 10.

Then, when the valve 10 is opened and closed, the liquid carbon dioxide gas stored in the storage tank is injected into the valve 10, and the injected liquid carbon dioxide gas passes through the valve 10 into the snow chamber part 20. Supplied.

The snow chamber portion 20 is formed inside the hollow portion, the upper surface of the snow chamber portion 20 is coupled to the gas outlet 22 of the tubular shape through which the gas is discharged.

Then, 50% of the liquid carbon dioxide gas supplied into the snow chamber 20 is accumulated from the bottom of the snow chamber while being generated as snow, and the temperature inside the snow chamber is at -60 ° C.

At this time, the remaining 50% of the liquid carbon dioxide except for 50% generated by snow is vaporized in the snow chamber 20 to generate a gas, the gas is a gas coupled to the upper surface of the snow chamber 20 Discharge through the outlet (22).

On the other hand, the snow accumulated from the inner bottom of the snow chamber 20 is dropped by its own weight, the circulation is accumulated while the snow is generated again by the liquid carbon dioxide continuously supplied to the snow chamber 20 again Is repeated.

Then, when the snow falls by its own weight, it is positioned inside the hydraulic piston part 30 which is located at the lower end of the snow chamber part 20, and the hydraulic piston part 30 is connected to the oil pressure generating part 40. Snow that is driven by the falling down by the self-weight pushed toward the outlet 50, the snow is continuously pushed and accumulated on the outlet side is piled up tightly to create a dry ice and at the same time to form the forming groove 52 of the outlet 50 Is discharged through.

The oil pressure generating unit 40 is an oil tank (P) positioned at one side of the oil pump (P) located at one side of the motor (M) and the motor (M), and the motor ( As the M) is driven, the oil pump P is operated, and the oil of the oil tank T is transferred to the hydraulic piston part 30 by the hydraulic pressure generated by the operation of the oil pump P, thereby providing the hydraulic piston. The driving unit 30 is driven.

In addition, dry ice having the same size and shape in the discharge port 50 and being compacted through a plurality of molding grooves 52 formed at predetermined intervals is discharged in the same size and shape as the molding groove 52. In addition, the discharged dry ice is cut into a predetermined size and used.

On the other hand, in the conventional dry ice manufacturing apparatus made as described above, the present invention solidifies the snow on the inner surface of the snow chamber unit 20 in the process of generating liquid carbon dioxide gas supplied into the snow chamber unit 20 as snow. That is, the snow is stuck in the frozen state so that the snow is not dropped by its own weight so that the heat exchange is performed at the outer periphery of the snow chamber part 20 so that the snow is in the snow chamber part 20. This is to prevent freezing on the side.

To this end, the present invention spirally wound the heat medium circulation tube 60 with no gap as the outer periphery of the snow chamber 20 as shown in Figures 2 and 3.

Then, the heat medium circulation pipe 60 is wound on the outer periphery of the snow chamber 20, and then one end of the heat medium circulation pipe 60 is connected to one side of the oil pump P of the hydraulic pressure generating unit 40, and the other end thereof. To one side of the oil tank (T).

In addition, the cover unit 70 is coupled to only the portion of the heat medium circulation tube 60 wound around the outer periphery of the snow chamber 20 in a spiral manner.

Then, as described above, after installing the heat medium circulation pipe 60 and the cover part 70 on the outer circumference of the snow chamber part 20, and opening and closing the valve 10, the snow chamber part 20 is provided. As liquid carbon dioxide is supplied to the inside and snow is generated, snow continuously accumulates from the bottom of the snow chamber part 20.

In addition, the snow accumulated in the snow chamber part 20 falls to the hydraulic piston part 30 by its own weight, and the hydraulic piston part 30 is driven by the hydraulic generating part 40 to the discharge port 50. Squeeze the snow in the direction of).

At the same time, the oil pump P of the hydraulic generator 40 is operated according to the driving of the motor M, and oil is injected into the heat medium circulation pipe 60, and the injected oil is again heated medium heat pipe 60. ) The process of discharging to the oil tank (T) is repeated along the inside.

At this time, the oil of about 40 ℃ circulated in the heat medium circulation tube 60 is used as the heat medium of the present invention, about 40 into the heat medium circulation tube 60 wound around the outer periphery of the snow chamber 20 As the heat medium (oil) of the temperature ℃ is to circulate the snow on the inner surface of the snow chamber portion 20 to prevent the phenomenon of freezing.

In addition, the cover portion 70 for accommodating the heat medium circulation pipe 60 wound around the outer periphery of the snow chamber 20 has an external temperature of the heat medium (oil) circulated into the heat medium circulation pipe 60. It is released to prevent the temperature is lowered, and serves to prevent the breakage of the heat medium circulation pipe 60 due to the impact from the outside.

Dry ice device according to the present invention made as described above, by the oil is circulated in the heat medium circulation tube wound around the outer periphery of the snow chamber portion, the effect of preventing the phenomenon that the snow accumulated on the inner surface of the snow chamber portion is frozen. There is a continuous dry ice manufacturing effect is made.

In addition, the cover portion for accommodating the heat medium circulation tube therein to prevent the temperature of the oil circulated into the heat medium circulation tube is discharged to the outside to lower the temperature, and to prevent damage of the heat medium circulation tube due to the impact from the outside It works.

Although the present invention has been described with reference to specific preferred embodiments, the present invention is not limited to the above-described embodiments, and the present invention is not limited to the scope of the present invention. Various changes and modifications can be made by the user.

Claims (1)

A valve 10 for adjusting a flow rate of the liquid carbon dioxide injected into one side thereof; As the valve 10 is opened and closed, some of the liquid carbon dioxide supplied into the snow is generated as snow, and the other is discharged through the gas outlet 22 coupled to the upper surface to discharge the gas generated by vaporization. A snow chamber unit 20; Hydraulic piston unit 30 to produce a dry ice chopped to fall by its own weight as the snow generated in the snow chamber 20 is stacked; An oil pressure generating unit (40) comprising an oil pump (P) and an oil tank (T) for supplying oil according to the driving of the motor (M) for the operation of the hydraulic piston unit (30); According to the driving of the hydraulic generator 40, a plurality of discharge grooves 50 having a plurality of forming grooves 52 having the same size at regular intervals such that the dry ice compacted by the hydraulic piston unit 30 is discharged in a predetermined size and the same shape. In the dry ice manufacturing apparatus consisting of: Spirally wound around the outer periphery of the snow chamber 20, one end thereof is connected to one side of the oil pump (P) of the hydraulic generator 40, the other end is connected to one side of the oil tank (T) A heat medium circulation pipe 60 through which the heat medium is circulated; The heat medium circulation pipe 20 is formed of a cover part 70 which receives a portion of the heat medium circulation pipe 20 spirally wound around the outer periphery of the snow chamber part 40 to prevent heat emission to the outside by receiving the inside thereof. Dry ice manufacturing apparatus characterized in that.