KR101129468B1 - liqiud nitrogen dispenser with triple layers structure having heating block - Google Patents

Abstract

The present invention relates to a liquid nitrogen injector of a triple piping structure in which a heating block is formed. The vacuum layer is primarily formed by forming a piping in which liquid nitrogen is injected, stored, and transported in a triple piping structure to insulate liquid nitrogen. Heat insulation by the liquid nitrogen layer is performed secondarily, and as a result, the temperature of the liquid nitrogen transferred to the injection nozzle is kept below the vaporization temperature. The liquid nitrogen injector of the triple piping structure in which the heating block is formed according to the present invention has a heating block installed around the injection nozzle, the vaporized nitrogen discharge part, and the liquid nitrogen injection part, thereby condensing water and freezing around the injection nozzle. Prevent throwing away.

Liquid nitrogen, spray, moisture, water vapor, ice

Description

Liquid nitrogen injector with triple piping structure with heating block {liqiud nitrogen dispenser with triple layers structure having heating block}

The present invention relates to a device for injecting liquid nitrogen to the outside with a predetermined injection amount, and liquid nitrogen having a triple piping structure in which a heating block is provided with a heater installed around the injection nozzle to prevent ice from being generated around the injection nozzle. It relates to an injection device.

Liquid nitrogen injector is a device that stores the liquid nitrogen supplied from the nitrogen tank while maintaining the ultra low temperature and injects it at a predetermined injection amount. It is previously used to drop liquid nitrogen into the interior of beverage cans. If the lid is sealed by covering the lid of the beverage can while the hot beverage is injected into the beverage can, the hot beverage cools and the air inside the beverage can shrinks, distorting the beverage can. Therefore, if the liquid nitrogen is dropped before the beverage can is sealed, the liquid nitrogen vaporizes to compensate for the shrinkage of the air, thereby maintaining the shape of the beverage can in a circular shape.

Nitrogen has a vaporization point of -196 ° C. Therefore, since the temperature of the liquid nitrogen is -196 ℃ or less, the piping of the portion where the liquid nitrogen is injected, stored, transported and injected, and the vicinity of the injection nozzle in which the liquid nitrogen is injected is cooled to very low temperature. Therefore, water vapor or moisture in the air condenses around the pipe and the injection nozzle of the liquid nitrogen inlet, the storage and the transfer part, and freezes, causing ice to continue to be generated and stacked. Eventually, it occurs until ice generated by condensation of water blocks the injection flow during injection of liquid nitrogen from the injection nozzle or blocks the injection nozzle.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems pointed out in the above-mentioned background, and an object of the present invention is to prevent the occurrence of ice in the vicinity of the injection nozzle, thereby smoothing the injection flow of liquid nitrogen in the injection nozzle, and It is to provide a liquid nitrogen injection device to prevent clogging.

An object of the present invention as described above, in the liquid nitrogen injector for injecting liquid nitrogen to the outside, the injection nozzle having a hole for injecting liquid nitrogen to the outside and the side of the injection nozzle to contact the lateral circumference of the injection nozzle The heating block is formed inside the through hole of the heating block so that the upper surface is in contact with the lower end of the injection nozzle and the heating block is formed in the periphery and allows the injection of the liquid nitrogen and connected to the heating block This is achieved by a liquid nitrogen injection device, characterized in that the guide hole connected to the hole of the injection nozzle comprises a moisture condensation preventing plug formed therein.

In order to achieve the above object, the outer surface of the injection nozzle is preferably formed with a groove for reducing the contact area with the heating block.

In order to achieve the above object, the heating block surrounds the outer surface of the injection nozzle to block the outer surface of the injection nozzle from the atmosphere, and the moisture condensation preventing plug has an outer surface in the hollow portion of the heating block. In close contact with the side surface and the upper surface is formed to be in close contact with the lower end of the injection nozzle, it is preferable that water vapor or moisture in the air is prevented from penetrating into the lower end of the injection nozzle through the hollow portion of the heating block.

According to the liquid nitrogen injector forming the heating block according to the present invention, the heating block and the water condensation prevention plug are wrapped around the injection nozzle, so that water vapor or moisture in the air can stick to the periphery of the injection nozzle and freeze. have.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the liquid nitrogen injector of the triple pipe structure with a heating block formed in accordance with a preferred embodiment of the present invention.

1 is a cross-sectional view of a liquid nitrogen injector of a triple piping structure having a heating block according to a preferred embodiment of the present invention, Figure 2 is a partial cross-sectional view showing the configuration of the periphery of the liquid nitrogen injector of FIG.

As shown in Figure 1 and 2, the liquid nitrogen injection device (hereinafter referred to as 'injection device') of the triple pipe structure with a heating block is formed according to a preferred embodiment of the present invention to the inside of the outer case (1) The liquid nitrogen supply unit 10, the liquid nitrogen storage unit 20, the guide passage 25, and the liquid nitrogen injection unit 30 are formed.

The space between the liquid nitrogen supply unit 10, the liquid nitrogen storage unit 20, the guide passage 25, and the liquid nitrogen injection unit 30 formed inside the outer case 1 and the outer case 1 is vacuumed. Layer 5 is formed to block heat transfer from the outside to the internal components. Nitrogen has a boiling point of -196 ° C. Therefore, it is very important for the injector to block heat transfer from the outside to the liquid nitrogen stored therein.

The liquid nitrogen supply unit 10 is formed to extend vertically as a space into which the liquid nitrogen supplied from the outside enters the liquid nitrogen storage unit 20 which will be described later. The liquid nitrogen supply unit 10 is connected to a liquid nitrogen injection tube 3 connected to a liquid nitrogen tank (not shown). The liquid nitrogen supply unit 10 is formed to be connected to the atmospheric pressure holding tube 2 having a passage connected to the outside air in order to maintain the internal pressure at atmospheric pressure. Atmospheric pressure holding tube (2) is to maintain the inside of the injector in which the liquid nitrogen is stored at atmospheric pressure and to perform the function of simultaneously discharging the vaporized nitrogen to the outside to increase the pressure inside the injector by the vaporized nitrogen prevent. As the pressure inside the injector increases, the amount of liquid nitrogen injection in the injection nozzle is changed to deviate from the intended injection amount. In the exposed portion of the liquid nitrogen injection tube 3 and the atmospheric pressure holding tube 2 at the top of the injector, it is surrounded by a heating block 7 so that the cryogenic liquid nitrogen condenses the vapor in the air and the liquid nitrogen injection tube 3 and It prevents freezing around the atmospheric pressure holding tube (2).

The liquid nitrogen storage unit 20 is connected to the liquid nitrogen supply unit 10 and stores the liquid nitrogen introduced through the liquid nitrogen supply unit 10. Inside the liquid nitrogen storage unit 20, an atmospheric container 22 having an open top structure is formed. The liquid nitrogen filled in the liquid nitrogen storage unit 20 flows through the upper portion of the atmospheric container 22 and flows into the atmospheric container 22.

The liquid nitrogen injection unit 30 is connected to the liquid nitrogen storage unit 20 through the guide passage 25 and at the same time connected to the atmospheric container 22 through the liquid nitrogen transfer pipe 28. The injection nozzle 70 is connected to the liquid nitrogen transfer pipe 28 and receives liquid nitrogen from the atmospheric container 22 to inject liquid nitrogen to the outside. The liquid nitrogen filled in the guide passage 25 is not directly supplied to the injection nozzle 70, and functions to cool the outside of the liquid nitrogen transfer pipe 28.

The injection process of liquid nitrogen is as follows. Liquid nitrogen introduced into the atmospheric container 22 installed in the liquid nitrogen storage unit 20 passes through the liquid nitrogen transfer pipe 28 and the nozzle adjacent space of the nozzle induction pipe 31 of the liquid nitrogen injection unit 30 ( 32, the liquid nitrogen is injected to the outside through the injection nozzle 70 formed on the lower end of the injection guide pipe (31). Injection of the liquid nitrogen is started by raising the opening and closing rod 40 of the liquid nitrogen injection unit 30. When the opening and closing rod 40 rises, the liquid nitrogen stored in the liquid nitrogen storage unit 20 is integrally connected to the atmospheric container 22, the liquid nitrogen transfer pipe 28, the injection guide tube 31, and the injection nozzle 70. It becomes a state. The liquid nitrogen supply unit 10 has an atmospheric pressure maintaining passage 3 formed thereon, so that the pressure inside the liquid nitrogen is maintained at atmospheric pressure, and thus, the liquid nitrogen storage unit 20 or the atmospheric container 22 to which the liquid nitrogen supply unit 10 is connected. Since the pressure of the surface of the liquid nitrogen is also atmospheric pressure and the outside of the injection nozzle 70 is the atmospheric pressure, the pressure of the liquid nitrogen corresponding to the difference between the height of the surface of the liquid nitrogen in the liquid nitrogen storage unit 20 and the height of the injection nozzle 70. By the liquid nitrogen is injected from the injection nozzle 70. That is, the injection of the liquid nitrogen is made by raising the opening and closing rod 40 without a separate power.

Hereinafter, the detailed configuration of the liquid nitrogen injection unit will be described.

3 is an enlarged view illustrating an enlarged configuration around the injection nozzle of FIG. 1. As shown in FIG. 3, the liquid nitrogen injection unit 30 is composed of components of the injection nozzle 70 and the periphery of the injection nozzle 70. Among the components around the injection nozzle 70, the outer case 1 is also included. The portion of the outer case 1 connected to the upper portion of the injection nozzle 70 is indicated as the lower surface 35 of the liquid nitrogen injection portion. The injection nozzle 70 is detachably coupled to the mounting portion 36 protruding downward from the lower surface 35 of the liquid nitrogen injection unit, and the injection nozzle 70 and the lower surface 35 of the liquid nitrogen injection unit. Heat transfer occurs between. Therefore, when the injection nozzle 70 is cooled, the lower surface 35 of the liquid nitrogen injection unit is also cooled.

The injection nozzle 70 is coupled to the mounting portion 36 formed below on the lower surface 35 of the liquid nitrogen injection unit, and a hole 72 in which liquid nitrogen is injected is formed at the lower end of the injection nozzle 70, and the injection is performed. The bottom surface 73 of the periphery of the hole 72 at the lower end of the nozzle 70 is formed in a plane to be in close contact with the top surface of the moisture condensation preventing plug 90 to be described later in close contact with each other.

The heating block 80 has a hollow portion 81 penetrated in the vertical direction at the center thereof and generates heat by receiving power. The heating block 80 is installed around the injection nozzle 70, and the inner surface 82 forming the hollow portion 81 of the heating block 80 has an outer circumference of the mounting portion 36 and the injection nozzle 70. The upper surface 85 of the heating block 80 is in close contact with the lower surface 35 of the liquid nitrogen injection unit connected to the upper portion of the injection nozzle 70.

The condensation preventing plug 90 is formed under the injection nozzle 70 in the hollow portion 81 of the heating block 80. Water condensation prevention plug 90 is formed by guiding holes (91, 92) through the center, the guide hole is formed of two stages of the interconnection of the upper guide hole 91 and the lower guide hole 92, the lower guide The inner diameter of the ball 92 is larger than the inner diameter of the upper guide hole 91 so that the liquid nitrogen injected from the injection nozzle 70 does not touch the inner side of the lower guide hole 92. The moisture condensation preventing plug 90 has a male thread portion 95 formed therein with a male thread along a circumference, and an upper surface 96 is formed in a flat shape, and the male thread portion 95 and the heating block of the moisture condensation preventing plug 90 are formed. The female thread portion 82 of the lower portion of the hollow portion 81 of the 80 is screwed so that the moisture condensation preventing plug 90 is installed on the heating block 80, and the upper surface 96 of the moisture condensation preventing plug 90 is provided. ) Is in close contact with the bottom surface 73 of the lower end of the injection nozzle (70). The upper guide hole 91 and the lower guide hole 92 of the moisture condensation preventing plug 90 are connected to the hole 72 of the injection nozzle 70 to enable the injection of liquid nitrogen. The injection nozzle 70 may be mounted to the mounting portion 36 of various lengths and sizes, wherein the moisture condensation preventing plug 90 is hollowed out of the heating block 80 according to the size or length of the injection nozzle 70. The mounting position on the part 81 should be different. Therefore, the moisture condensation preventing plug 90 was formed in a detachable structure with the heating block 80 and at the same time by screwing with the heating block 80 to enable the position adjustment in the vertical direction. Accordingly, by adjusting the position of the moisture condensation preventing plug 90, the bottom surface 73 of the spray nozzle 70 and the upper surface 96 of the moisture condensation preventing plug 90 may be contacted.

The heating block 80 is in close contact with the lower surface 35 of the liquid nitrogen jetting part which is connected to the circumference of the jetting nozzle 70 and the upper part of the jetting nozzle 70. Therefore, the contact of water vapor or moisture in the air with the circumference of the injection nozzle 70 and the lower surface 35 of the liquid nitrogen injection unit is blocked. In addition, since the heating block 80 itself generates heat to maintain a temperature of about 30 degrees Celsius, water vapor or moisture in the air around the heating block 80 is prevented from freezing after condensation or condensation on the heating block 80. The reason why the temperature of the heating block 80 is maintained at about 30 degrees Celsius is to maintain the temperature higher than the atmospheric temperature, and at a temperature higher than the atmospheric temperature, water vapor or moisture in the atmosphere does not condense on the heating block 80. .

The heating block 80 is in close contact with the outer surface of the injection nozzle 70, the hollow portion 81 is formed in the vertical direction, and because of the hollow portion 81 is not in direct contact with the lower end of the injection nozzle 70 It does not transfer heat directly to the bottom of the injection nozzle (70). Therefore, when water vapor or water contained in the atmosphere penetrating upward through the hollow portion 81 directly below the heating block 80 comes into contact with the lower end of the injection nozzle 70, water vapor or moisture is applied to the lower end of the injection nozzle 70. It condenses and freezes. Therefore, the injection device of the present invention installed a moisture condensation preventing plug 90 in the hollow portion 81 of the heating block (80).

The water condensation preventing plug 90 has a male thread portion 95 in close contact with the inner surface 82 of the hollow portion 81 of the heating block 80. Therefore, the moisture condensation preventing plug 90 receives heat from the heating block 80 through the inner surface 82 of the hollow portion 81 of the heating block 80 to maintain a predetermined temperature. The moisture condensation prevention plug 90 blocks the hollow portion 81 of the heating block 80 because the whole block the hollow portion 81 of the heating block 80 except for the upper guide hole 91 in the vertical direction. Moisture or water in the air through it prevents the penetration of the lower end of the injection nozzle (70). Moisture condensation prevention plug 90 has an upper guide hole 91 does not completely block the hollow portion 81 of the heating block 80 in the vertical direction, but the upper guide hole 91 of the moisture condensation prevention plug 90 Is in close contact with the lower end of the spray nozzle 70, the lower end of the spray nozzle 70 has the effect of blocking the guide hole of the water condensation preventing plug 90, and at the same time liquid nitrogen in the hole 72 of the spray nozzle 70 Is sprayed, and consequently, due to the water condensation preventing plug 90, water vapor or moisture in the air cannot pass through the lower end of the spray nozzle 70 and penetrate into other parts of the spray nozzle 70.

As a result, the injection nozzle 70 and the lower surface 35 of the liquid nitrogen injection unit around the injection nozzle 70 are surrounded by the heating block 80 and the moisture condensation preventing plug 90 to inject water vapor or moisture contained in the outside air. The nozzle 70 and the injection nozzle 70 do not penetrate into the lower surface 35 of the liquid nitrogen injection unit and are not in contact with each other. However, water vapor or moisture in the air is not heated and the water condensation preventing plug 90. Although the heating block 80 and the moisture condensation prevention plug 90 maintain a temperature of 0 degrees Celsius or more, water vapor or moisture in the air sticks to the heating block 80 and the moisture condensation prevention plug 90. Even if it does not freeze ice does not form. In addition, if the temperature of the heating block 80 and the moisture condensation prevention plug 90 is kept higher than the temperature of the atmosphere, for example, about 30 degrees Celsius, water vapor or moisture in the air is heated and the moisture condensation prevention plug 90 Even condensation can be prevented.

If there is no heating block 80 or moisture condensation preventing plug 90 around the injection nozzle 70, since the liquid nitrogen injected through the injection nozzle 70 is very low temperature, the injection nozzle 70 or the injection nozzle 70 Water vapor or moisture in the atmosphere condenses and freezes around the ice, and the ice melts and freezes repeatedly to block the holes 72 of the spray nozzle 70. In addition, the ice frozen in the vicinity of the injection nozzle 70 melts and falls down, so the working environment worsens and dirty the surroundings are not good.

Hereinafter, the configuration and effect of the heater formed in the pneumatic cylinder support portion will be described.

The liquid nitrogen injection unit 30 is formed with an injection guide tube 31 connected to the liquid nitrogen transfer pipe 28.

Injection guide pipe 31 is formed in the nozzle adjacent space 32 is filled with liquid nitrogen in the vertical direction long and the bottleneck 33 is formed to narrow the width of the passage downward and below the bottleneck 33 An injection nozzle 70 is formed at the end of the passage connected to the nozzle. The opening and closing rod guide portion 34, which is a passage through which the opening and closing rod 40 can enter and retract, is formed at an upper portion of the injection guide pipe 31, and a pair of O-rings 37 are formed at the inner circumference of the opening and closing rod guide 34. These are formed apart from each other in the vertical direction. O-rings 37 of the opening and closing bar guide 34 are in close contact with the outer surface of the opening and closing bar 40 to prevent leakage of liquid nitrogen from the nozzle adjacent space 32 to the outside of the opening and closing bar guide 34.

4 is an enlarged view illustrating an enlarged configuration of a periphery of the pneumatic cylinder supporter of FIG. 1. As shown in Figure 2 and 4, the opening and closing rod 40 is installed through the opening and closing rod guide 34 of the injection guide pipe 31, the opening and closing rod 40 enters the nozzle adjacent space (32) The lower end of the opening and closing rod 40 while closing or retracting closes or opens the bottleneck 33 of the injection guide pipe (31). The upper one side of the opening and closing rod 40 is formed with a lower hole 41 to the outside of the opening and closing rod 40. The lower hole 41 is connected to the passage 42 formed inside the opening / closing rod 40, and the passage 42 inside the opening / closing rod 40 extends upwards and the end portion extending upwards is expanded space. To form 43. An upper hole 45 is formed at an outer side of the upper portion of the opening and closing rod 40 above the lower hole 41. The upper hole 45 of the opening and closing rod 40 is connected to the expanded space 43 at the upper end of the passage 42 inside the opening and closing rod 40. The rear end of the opening / closing rod 40 is connected to the pneumatic cylinder 50 to move up and down by the pneumatic cylinder 50.

The pneumatic cylinder support portion 55 is formed above the injection guide pipe 31. The pneumatic cylinder support portion 55 is formed in a tubular structure to support the lower end of the pneumatic cylinder 50, and the inner space 56 formed inside the tubular structure accommodates the rear portion of the opening and closing rod 40. One side of the pneumatic cylinder support portion 55 is formed with a communication hole 57 for connecting the sealed inner space 56 of the tubular structure to the outside.

The heater 60 is installed to surround the outer circumference of the pneumatic cylinder support part 55. The inner circumference of the heater 60 is formed with a circumferential groove 62 connected to the communication hole 57 of the pneumatic cylinder support unit 55, and the heater 60 is disposed at one side of the circumferential groove 62 of the heater 60. Outside air connection hole 64 is formed to communicate with the outside air to the outer side of the). Since the vaporized nitrogen is very low temperature, the pneumatic cylinder support unit 55 may be cooled, and moisture such as water vapor may freeze outside the cooled pneumatic cylinder support unit 55, thereby blocking the communication hole 57 of the pneumatic cylinder support unit 55. Therefore, the heater 60 selectively heats the pneumatic cylinder support 55 so that moisture does not freeze to the pneumatic cylinder support 55. The circumferential groove 62 and the external air connection hole 64 of the heater 60 eventually connect from the lower hole 41 of the opening / closing rod 40 to the outside air of the heater 60.

The heater surrounding the outer side of the pneumatic cylinder support unit 55 is for preventing moisture or water vapor in the air from condensing and freezing on the pneumatic cylinder support unit 55 by nitrogen vaporized and discharged from the nozzle adjacent space. Vaporized nitrogen generated in the nozzle adjoining space 32 rises in the state in which the opening / closing rod 40 rises upward, flows into the lower hole 41 of the opening / closing rod 40, and the passage 42 inside the opening / closing rod 40. It moves through and exits the upper hole 45 of the opening and closing rod 40 through the expanded space 43, the communication hole 57 of the pneumatic cylinder support portion 55 and the circumferential groove 62 of the heater 60 And it is discharged to the outside through the outside air connection hole 64.

Since the vaporized nitrogen is also very low temperature, the pneumatic cylinder support portion 55 from which the vaporized nitrogen is discharged is cooled to a very low temperature, and moisture or water vapor in the atmosphere outside the pneumatic cylinder support portion 55 is applied to the pneumatic cylinder support portion 55. Condensation and freezing may cause ice, and eventually the communication hole 57 of the pneumatic cylinder support 55 may be blocked by the ice. Therefore, the heater 60 is formed around the pneumatic cylinder support part 55, and the cylindrical groove 62 and the external air connection hole 64 connected to the communication hole 57 of the pneumatic cylinder support part 55 in the heater 60. Formed to prevent the evaporated nitrogen is discharged at the same time the ice is formed in the pneumatic cylinder support (55).

The outer surface of the spray nozzle 70 preferably shields as much of the area from the atmosphere as possible to block condensation of water vapor. However, the smaller the heat is transferred from the heating block 80 to the outer surface of the injection nozzle 70. This is because the heat transferred to the injection nozzle 70 vaporizes liquid nitrogen. This is because when the liquid nitrogen is vaporized, the injection amount set on the basis of the initial liquid nitrogen is wrong, which is undesirable. Therefore, in order to minimize heat transfer, the smaller the contact area between the outer surface of the spray nozzle 70 and the heating block 80 is, the better the recess area is formed by forming grooves 75 on the outer surface of the spray nozzle 70. .

1 is a cross-sectional view of a liquid nitrogen injector of a triple piping structure with a heating block according to an embodiment of the present invention,

2 is a partial cross-sectional view showing the configuration of the periphery of the liquid nitrogen injection unit of FIG.

FIG. 3 is an enlarged view illustrating an enlarged configuration around the injection nozzle of FIG. 1;

4 is an enlarged view illustrating an enlarged configuration of a periphery of the pneumatic cylinder supporter of FIG. 1.

Claims (3)

In the liquid nitrogen injector for injecting liquid nitrogen to the outside, An injection nozzle having a hole for injecting liquid nitrogen to the outside; A heating block formed around the lateral circumference of the injection nozzle to contact the lateral circumference of the injection nozzle and having a perforated hollow portion allowing injection of liquid nitrogen; And A moisture condensation prevention plug having an upper surface formed inside the hollowed portion of the heating block so as to contact the lower end of the injection nozzle, and connected to the heating block to generate heat, and a guide hole connected to the hole of the injection nozzle is formed therein. Including, The heating block surrounds the outer surface of the injection nozzle to block the outer surface of the injection nozzle from the atmosphere, The moisture condensation preventing plug is formed so that the outer side is in close contact with the hollow portion of the heating block and the upper surface is in close contact with the lower end of the spray nozzle, so that water vapor or moisture in the air is sprayed through the hollow portion of the heating block. Liquid nitrogen injection device of a triple piping structure formed with a heating block, characterized in that the penetration of the lower end of the nozzle is prevented. The liquid nitrogen injector of claim 1, wherein a groove is formed on an outer surface of the injection nozzle to reduce a contact area with the heating block. delete

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