KR100793547B1 - Apparatus for making Refrigerant from LCO2 - Google Patents

Abstract

The present invention provides a refrigerant manufacturing apparatus for producing a solid refrigerant using liquefied carbon dioxide gas, the body having a lower plate; A molding frame disposed to be spaced apart from an upper surface of the lower plate and having an empty hollow inside and integrally formed to open the upper end and the lower end; The injection nozzle inserted into the hollow portion of the forming mold and the liquefied carbon dioxide tank in which the injection nozzle and the liquefied carbon dioxide gas are stored so that the liquefied carbon dioxide gas is supplied to the injection nozzle, A supply member including a supply pipe having a valve to control the supply; One side is positioned and mounted on the lower plate of the main body so that the solid refrigerant is generated by applying pressure to the liquefied carbonic acid gas supplied to the molding die, and the other side is a lower hydraulic cylinder inserted in close contact with the open lower end of the molding die. And an upper hydraulic cylinder which is installed to be spaced apart from the mold, and whose one surface is formed to correspond to the upper end of the mold to close the open top of the mold, and the solid refrigerant generated in the mold. A cylinder member including a blow-out hydraulic cylinder positioned at one side of the upper end of the mold to blow out the furnace; And a control unit mounted to the main body to control the valve or the cylinder member, the chute positioned at the other end of the upper side of the forming die to accommodate the solid refrigerant drawn out from the forming die. The apparatus for manufacturing a solid refrigerant using liquefied carbon dioxide, characterized in that for controlling the size of the solid refrigerant generated in the mold to control the moving distance of the lower hydraulic cylinder inserted into the lower end of the mold by the control unit will be.

The solid refrigerant production apparatus using the liquefied carbon dioxide according to the present invention using the valve and the cylinder member that is automatically controlled, it is possible to automatically produce when manufacturing the solid refrigerant, labor costs are saved, production per unit time increases, various sizes There is an effect that can produce a solid refrigerant of.

Liquefied carbon dioxide, forming mold, supply member, cylinder member

Description

Apparatus for producing solid refrigerant using liquefied carbon dioxide {Apparatus for making Refrigerant from LCO2}

1 is a perspective view of a conventional refrigerant production apparatus.

Figure 2 is an internal front view showing a solid refrigerant production apparatus using liquefied carbon dioxide according to the present invention.

Figure 3 is an internal side view showing a solid refrigerant production apparatus using liquefied carbonic acid gas according to the present invention.

Figure 4 is a plan view showing a state in which the cover is removed in the solid refrigerant production apparatus using liquefied carbon dioxide according to the present invention.

5 is a schematic diagram showing an apparatus for producing a solid refrigerant using liquefied carbon dioxide according to the present invention.

Figure 6 is a flow chart illustrating a sequence of operating the hydraulic cylinder of the solid refrigerant production apparatus using the liquefied carbon dioxide according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: main body 12: lower plate

13: wheel for movement 14: support frame

15: Upper plate 16: Support plate

17: guide frame 20: forming mold

22: discharge means 30: supply member

32: injection nozzle 34: supply pipe

40: cylinder member 42: electric motor

44: lower hydraulic cylinder 46: upper hydraulic cylinder

48: ejection hydraulic cylinder 50: chute

60: cover 70: control unit

The present invention relates to an apparatus for producing solid refrigerant using liquefied carbonic acid gas, and more particularly, by using an automatically controlled valve and cylinder member, liquefied carbonic acid capable of automatic production during solid state refrigerant production and labor costs can be saved. The present invention relates to a solid refrigerant production apparatus using gas.

In general, a solid refrigerant such as dry ice is made of a solid by cooling carbon dioxide, and sublimes immediately without liquefying at normal pressure, and the sublimation point is minus 78.5 ° C.

Such dry ice is used in various industries because it melts like ice and does not become a liquid, but becomes a gas and leaves no residue. Especially, dry ice is not only used to cool foods and other items, but also sodium carbonate and urea. It is also used in large quantities in the manufacture of soft drinks, welding and castings.

Meanwhile, ice cream or aquatic products are transported and stored at a low temperature of frozen or refrigerated, where a solid refrigerant such as ice or dry ice is put into an ice container and transported and stored.

However, when ice is used, it can only be stored at about 2 ° C to 8 ° C, which limits its use, and it must be replaced frequently because it melts easily during transportation.If the ice melts, the quality of stored items will be adversely affected. There is a problem.

The use of dry ice has the advantage of keeping the frozen or refrigerated state more stable. However, since solid refrigerants such as dry ice tend to evaporate easily at room temperature due to their inherent characteristics, they have to be frequently supplied with refrigerant. There is a feeling.

In order to solve the above problems, development of a solid refrigerant production apparatus using a mobile liquefied carbonic acid gas capable of directly producing a refrigerant in a place where a refrigerant is required has been required.

Korean Laid-Open Patent Publication No. 2001-0003810 discloses a refrigerant manufacturing apparatus that can directly manufacture a refrigerant in the field using liquefied carbon dioxide, and FIG. 1 is a perspective view of a manufacturing apparatus used in the patent.

Referring to FIG. 1, a conventional refrigerant manufacturing apparatus includes a supply pipe (not shown) connected to a carbon dioxide tank (not shown), and a carbon dioxide gas injector (not shown) connected to the supply pipe, and the carbon dioxide gas injector is a solenoid. It includes an injection pipe (not shown) having a valve (not shown) connected to the supply pipe, a controller (not shown) for controlling the solenoid valve, and a forming mold 100 to be connected to the injection pipe. .

The forming mold 100 is divided into an upper mold 110 and a lower mold 120, and the upper mold 110 and the lower mold 120 are provided with a plurality of exhaust holes 112a and 122a, respectively. The portion 112 and the lower accommodation portion 122 are formed in a corresponding shape, and a filter (not shown) is attached to contact the exhaust holes 112a and 122a and sprayed on one side of the lower accommodation portion 122. The nozzle 130 is attached.

Conventional refrigerant production apparatus using the liquefied carbon dioxide configured as described above has the advantage that it is easy to move to the site requiring the refrigerant, and can also produce the refrigerant directly on site according to the demand amount.

However, the conventional refrigerant manufacturing apparatus, when opening and closing the upper frame 110 and the lower frame 120, must be opened and closed manually, in this process to closely close the upper frame 110 and the lower frame 120 to each other. Since it is difficult, the high pressure liquefied carbonic acid gas supplied into the mold 100 during the manufacture of the refrigerant is discharged through the surfaces in contact with each other of the upper mold 110 and the lower mold 120. As a result, there is a problem that a worker is highly at risk of poisoning and injury to carbon dioxide due to the high pressure liquefied carbon dioxide discharged.

In addition, since the thickness of the refrigerant is determined by the size of the molding die 100 having the upper mold 110 and the lower mold 120, there is a problem that it is difficult to arbitrarily adjust the thickness of the refrigerant.

In order to solve the problems of the prior art as described above, an object of the present invention is to use the liquefied carbon dioxide gas that can be automatically produced in the manufacture of solid refrigerant, and the labor cost can be saved by using the valve and the cylinder member is automatically controlled It is to provide a solid refrigerant production apparatus.

Another object of the present invention is to form a molded mold integrally so that the high-pressure liquefied carbonic acid gas is not discharged into the workplace during the manufacture of a solid refrigerant, the solid using the liquefied carbonic acid gas to prevent workers from poisoning and injury due to the liquefied carbonic acid gas It is to provide a refrigerant production apparatus.

Still another object of the present invention is to provide an apparatus for preparing a solid refrigerant using liquefied carbonic acid gas, in which the volume of the solid refrigerant can be adjusted by arbitrarily adjusting the volume of the mold of the liquefied carbonic acid gas.

In order to achieve the above object, the present invention provides a refrigerant production apparatus for producing a solid refrigerant using liquefied carbon dioxide gas, the body having a lower plate; A molding frame disposed to be spaced apart from an upper surface of the lower plate and having an empty hollow inside and integrally formed to open the upper end and the lower end; The injection nozzle inserted into the hollow portion of the forming mold and the liquefied carbon dioxide tank in which the injection nozzle and the liquefied carbon dioxide gas are stored so that the liquefied carbon dioxide gas is supplied to the injection nozzle, A supply member including a supply pipe having a valve to control the supply; One side is positioned and mounted on the lower plate of the main body so that the solid refrigerant is generated by applying pressure to the liquefied carbonic acid gas supplied to the molding die, and the other side is a lower hydraulic cylinder inserted in close contact with the open lower end of the molding die. And an upper hydraulic cylinder which is installed to be spaced apart from the mold, and whose one surface is formed to correspond to the upper end of the mold to close the open top of the mold, and the solid refrigerant generated in the mold. A cylinder member including a blow-out hydraulic cylinder positioned at one side of the upper end of the mold to blow out the furnace; And a control unit mounted to the main body to control the valve or the cylinder member, the chute positioned at the other end of the upper side of the forming die to accommodate the solid refrigerant drawn out from the forming die. It provides a solid refrigerant production apparatus using liquefied carbon dioxide, characterized in that for controlling the size of the solid refrigerant generated in the mold to control the moving distance of the lower hydraulic cylinder inserted into the lower end of the mold by the control unit. do.

In addition, the present invention provides a solid refrigerant production apparatus using liquefied carbon dioxide, characterized in that the wheel for movement is mounted on the lower surface of the lower plate of the main body.

In addition, the present invention is a solid refrigerant using liquefied carbonic acid gas, characterized in that at least one discharge means is installed on one side of the mold to discharge the carbon dioxide gas is evaporated while the solid refrigerant is produced in the mold It provides a manufacturing apparatus.

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Hereinafter, a solid refrigerant production apparatus using liquefied carbonic acid gas according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

Figure 2 is an internal front view showing a solid refrigerant production apparatus using liquefied carbon dioxide according to the present invention, Figure 3 is an internal side view showing a solid refrigerant production apparatus using liquefied carbon dioxide according to the present invention, Figure 4 In the solid refrigerant production apparatus using the liquefied carbon dioxide according to the invention is a plan view showing a state in which the cover is removed.

2 to 4, the solid refrigerant producing apparatus 1 using the liquefied carbonic acid gas of the liquefied carbonic acid gas tank (not shown) according to a preferred embodiment of the present invention is the main body 10, the mold 20, And a discharge means 22 (shown in FIG. 5), a supply member 30 (shown in FIG. 5), a cylinder member 40, a chute 50 and a control unit 70.

The main body 10 is supported by the lower plate 12 having a predetermined width, a support frame 14 vertically coupled to the four corners of the upper surface of the lower plate 12 and the support frame 14 and the lower plate 12. The upper plate 15 is positioned to be spaced apart from the upper surface of the ().

In addition, the lower surface of the lower plate 12 is equipped with a moving wheel 13 to move the main body 10 easily.

In addition, between the upper plate 15 and the lower plate 12, a lower hydraulic cylinder 44 to be described later and a support plate 16 for supporting the guide frame 17 to be described later are positioned and mounted.

Guide frame 17 is one side is mounted on the four corners of the support plate 16, the other side is penetrated through the upper plate 15, the upper hydraulic cylinder 46 to be described later on the upper end of the molding frame 20 to be described later Guide to be installed at a predetermined distance.

Molding mold 20 is used to make a solid refrigerant by injecting liquefied carbonic acid gas, is installed on the upper plate 15 which is positioned to be spaced apart from the upper surface of the lower plate 12, so that the solid refrigerant is formed It has an empty hollow portion (not shown) inside, and is formed in one piece with the upper and lower ends open so that the lower hydraulic cylinder 44 and the upper hydraulic cylinder 46 to be described later are inserted.

One side of the mold 20 is provided with one or more discharge means 22 (shown in FIG. 5) to discharge carbon dioxide gas which is vaporized and remains while the solid refrigerant is manufactured in the mold 20. The means 22 is preferably composed of a gas exhaust filter.

The supply member 30 (FIG. 5 shown) includes an injection nozzle 32 (FIG. 5 shown) and a supply pipe 34 (FIG. 5 shown), and first, the injection nozzle 32 is provided in the hollow part of the forming die 20. Inserted and ejected liquefied carbonic acid gas to the hollow portion of the mold 20.

The supply pipe 34 is formed of a general pipe for supplying gas, so that the liquefied carbon dioxide gas of the liquefied carbon dioxide tank (not shown) is supplied to the forming mold 20 through the injection nozzle 32, and one side of the injection nozzle And the other side thereof is connected to the liquefied carbon dioxide tank.

In addition, a predetermined portion of the supply pipe 34 is equipped with a valve (not shown) to control the supply of the liquefied carbon dioxide gas supplied to the mold 20 through the supply pipe 34, the valve is a control unit 70 to be described later It is preferably composed of a solenoid valve that is automatically opened and closed in response to an electrical signal of).

The cylinder member 40 includes an electric motor 42 for generating power, a hydraulic pump (not shown) mechanically connected to the electric motor 42 to generate hydraulic energy, and a hydraulic pressure generated by the hydraulic pump. It includes a working hydraulic cylinder.

The hydraulic cylinder is a conventional, the lower hydraulic cylinder 44 is inserted into the open lower end of the molding die 20 to apply pressure to the molding die 20, a predetermined distance from the upper portion of the molding die 20 When the pressure is applied to the mold 20 by the lower hydraulic cylinder 44, the liquefied carbonic acid gas supplied to the mold 20 is prevented from leaking out of the mold 20, It comprises an upper hydraulic cylinder 46 for closing the upper portion and a blowout hydraulic cylinder 48 for taking out the solid refrigerant generated in the mold 20 to the outside.

The lower hydraulic cylinder 44 is one side is positioned and mounted on the upper surface of the lower plate 12, the other side is inserted in close contact with the lower end of the molding die 20, the molding die 20 through the supply member 30 Compress the liquefied carbon dioxide gas supplied to the.

The upper hydraulic cylinder 46 is installed on the other side of the guide frame 17 and is positioned to be spaced apart from the molding die 20 upwardly, and one surface of the upper hydraulic cylinder 46 corresponds to the upper end of the molding die 20. It is formed to be. Thus, when the lower hydraulic cylinder 44 compresses the liquefied carbonic acid gas supplied to the molding die 20, one surface of the upper hydraulic cylinder 46 is guided to the guide frame 17 to be folded up and down to form the molding die 20. To close the open top.

The blow-out hydraulic cylinder 48 is to blow out the solid refrigerant generated in the molding die 20 by the lower hydraulic cylinder 44 and the upper hydraulic cylinder 46, the molding die 20 on the upper plate 15 It is positioned and installed on the same line as the upper one side of the.

Chute (50) is located on the other side of the upper end of the mold 20 so that the solid refrigerant is received when the solid refrigerant generated in the mold 20 is blown out by the blow-out hydraulic cylinder 48 And are installed. One surface of the chute 50 is preferably formed to be flat so that the solid refrigerant to be taken out naturally slide, one side of the chute 50 is further provided with a receiving member (not shown) to accommodate the solid refrigerant that is sliding and falling down Can be.

The main body 10 includes a cover 60 to surround the lower plate 12, the support frame 14, the upper plate 15, the support plate 16, the forming mold 20, and the cylinder member 40. Additionally formed.

The control unit 70 for controlling the valve or the cylinder member 40 of the supply member 30 is disposed at a predetermined position of the cover 60, the control unit 70 is turned on (On) or off ( Off) a power switch (not shown), a conversion switch (not shown) for converting the solid refrigerant production into a manual or automatic process, and a cylinder member 40 during the manual process to control the semi-automatic production of the solid refrigerant. And a software unit (not shown) in which the solid refrigerant manufacturing process is preprogrammed to automatically manufacture the solid refrigerant by controlling the valve and the cylinder member 40 during the automatic process.

Hereinafter, the operation of the solid refrigerant production apparatus using the liquefied carbonic acid gas according to a preferred embodiment of the present invention will be described in detail.

5 is a schematic view showing a solid refrigerant production apparatus using the liquefied carbon dioxide according to the present invention, Figure 6 is a flow chart showing a sequence of operating the hydraulic cylinder of the solid refrigerant production apparatus using the liquefied carbon dioxide according to the present invention. .

Referring to the drawings, the solid refrigerant production apparatus 1 using the liquefied carbonic acid gas of the liquefied carbonic acid gas tank (not shown) according to a preferred embodiment of the present invention can be manually or automatically controlled by the operator, first The manual process controls the control switch of the control unit 70 to turn on the power, and then position the conversion switch in the manual state.

When the start button (not shown) is pressed, the electric motor 42 is operated to allow the lower hydraulic cylinder 44 of the hydraulic cylinder to be tightly inserted into the lower end of the molding die 20, and the upper hydraulic pressure of the hydraulic cylinder. The cylinder 46 causes the upper end of the mold 20 to be closed so that the hollow portion of the mold 20 is sealed.

And when the lower hydraulic cylinder 44 is inserted into the lower end of the mold 20, the operator using the control unit 70, by arbitrarily adjusting the moving distance of the lower hydraulic cylinder 44, The closed volume of the hollow part is adjusted to adjust the size of the solid refrigerant generated in the mold 20.

Thereafter, an operator arbitrarily sets a time of a timer (not shown) of the controller 70 so that the liquefied carbon dioxide is injected into the hollow portion of the forming mold 20 for a predetermined time.

At this time, according to the supply amount of the liquefied carbon dioxide gas injected into the mold 20 to produce a solid refrigerant produced in the mold 20 more firmly, it is possible to produce a high quality solid refrigerant.

When the liquefied carbonic acid gas is supplied to the mold 20 as described above, the lower hydraulic cylinder 44 inserted into the lower end of the mold 20 further receives the liquefied carbonic acid gas injected into the mold 20 by the software unit. By compression, a solid solid refrigerant is produced, and some vaporized gas is discharged to the outside through the discharge means 22.

The software unit raises the upper hydraulic cylinder 46 to open the upper end of the forming mold 20, and then raises the lower hydraulic cylinder 44 again to take out the generated solid refrigerant to the outside. The coolant is positioned at the top of the mold 20.

The solid refrigerant located at the upper end of the mold 20 is taken out and accommodated in the chute 50 by the withdrawal hydraulic cylinder 48 of the hydraulic cylinder advanced in the chute 50 direction.

Since the solid refrigerant generated in the mold 20 is discharged to the outside by the blow-out hydraulic cylinder 48, the operator does not need to take out the solid refrigerant from the dangerous mold 20, due to the carelessness of the operator Safety accidents that pinch the hand in the mold 20 does not occur.

The automatic process controls the power switch of the controller 70 to turn on the power, and then places the conversion switch in the automatic state.

Then, when the start button is pressed, the software unit is operated to operate the electric motor 42 so that the lower hydraulic cylinder 44 is inserted into the lower end of the molding die 20, and the upper hydraulic cylinder 46 causes the molding die. The upper end of the 20 is closed so that the hollow part of the molding die 20 is closed.

And when the lower hydraulic cylinder 44 is inserted into the lower end of the molding die 20, the moving distance of the lower hydraulic cylinder 44 is adjusted by the software input in advance, thereby the hollow portion of the molding die 20 The volume to be sealed is adjusted to arbitrarily adjust the size of the solid refrigerant generated in the mold 20.

Thereafter, the valve is opened for a predetermined time by the software portion input in advance, and liquefied carbonic acid gas is injected into the hollow portion of the forming mold 20 through the injection nozzle 32.

At this time, according to the supply amount of the liquefied carbon dioxide supplied to the mold 20 to produce a solid refrigerant produced in the mold 20 more firmly, it is possible to produce a high quality solid refrigerant.

In addition, since the process of generating the solid refrigerant by the lower hydraulic cylinder 44 and the upper hydraulic cylinder 46 and the process of taking out the chute 50 by the ejecting hydraulic cylinder 48 are the same as the manual process, more detailed description Will be omitted.

The automatic process is continuously performed by the software unit inputted in advance so that the solid refrigerant is automatically produced, thereby significantly improving productivity, saving labor costs, and reducing production costs. .

As described so far, the solid refrigerant production apparatus using the liquefied carbonic acid gas of the present invention can be automatically produced during the production of solid refrigerant by using a valve and a cylinder member that is automatically or manually controlled, the labor cost is reduced have.

While the invention has been described in detail in the foregoing embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

As described above, the solid refrigerant production apparatus using the liquefied carbonic acid gas according to the present invention by using a valve and a cylinder member that is automatically or manually controlled, it is possible to automatically produce when the solid refrigerant is produced, labor cost saving effect have.

In addition, the solid refrigerant production apparatus using the liquefied carbonic acid gas according to the present invention is formed by forming a mold so that the high-pressure liquefied carbonic acid is not discharged during the production of the solid refrigerant, so that workers are not poisoned and injured by the liquefied carbonic acid gas It is effective.

In addition, the solid refrigerant production apparatus using the liquefied carbonic acid gas according to the present invention has an effect that the thickness of the solid refrigerant can be adjusted by arbitrarily adjusting the supply amount of the liquefied carbonic acid gas.

Claims (5)

In the refrigerant production apparatus for producing a solid refrigerant using liquefied carbonic acid gas, A main body having a bottom plate; A molding frame disposed to be spaced apart from an upper surface of the lower plate and having an empty hollow inside and integrally formed to open the upper end and the lower end; The injection nozzle inserted into the hollow portion of the forming mold and the liquefied carbon dioxide tank in which the injection nozzle and the liquefied carbon dioxide gas are stored so that the liquefied carbon dioxide gas is supplied to the injection nozzle, A supply member including a supply pipe having a valve to control the supply; One side is positioned and mounted on the lower plate of the main body so that the solid refrigerant is generated by applying pressure to the liquefied carbonic acid gas supplied to the molding die, and the other side is a lower hydraulic cylinder inserted in close contact with the open lower end of the molding die. And an upper hydraulic cylinder which is installed to be spaced apart from the mold, and whose one surface is formed to correspond to the upper end of the mold to close the open top of the mold, and the solid refrigerant generated in the mold. A cylinder member including a blow-out hydraulic cylinder positioned at one side of the upper end of the mold to blow out the furnace; And a controller mounted to the main body to control the valve or the cylinder member. It includes a chute located on the other side of the upper end of the mold to accommodate the solid refrigerant drawn out from the mold, Apparatus for producing a solid refrigerant using liquefied carbon dioxide, characterized in that for controlling the size of the solid refrigerant generated in the mold to adjust the moving distance of the lower hydraulic cylinder inserted into the lower end of the mold . The method of claim 1, Apparatus for producing a solid refrigerant using liquefied carbon dioxide, characterized in that the wheel for movement is mounted on the lower surface of the lower plate of the main body. The method of claim 1, The apparatus for producing a solid refrigerant using liquefied carbonic acid gas, characterized in that at least one discharge means is installed on one side of the mold to discharge the carbon dioxide gas is evaporated and remaining during the manufacturing of the solid refrigerant in the mold. delete delete

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