JP2986009B2 - Liquid nitrogen visual recognition device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for visually confirming liquid nitrogen, and more particularly to a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder and a device to be cooled. The present invention relates to an apparatus for visually confirming the state of liquid nitrogen to be sent.

[0002]

2. Description of the Related Art In order to conduct physical properties research and application experiments on high-temperature superconducting materials, it is necessary to maintain a predetermined experimental device at a cryogenic temperature. Typically, liquid nitrogen and liquid helium are used as refrigerants. In this case, when using liquid helium, since the latent heat of liquid helium is small and expensive, first cool to a predetermined temperature with liquid nitrogen, and then use liquid helium to the required temperature. It is made to descend.

As described above, liquid nitrogen is used for pre-cooling or auxiliary cooling not only when cooling to the temperature of liquid nitrogen, but also when a lower temperature is required. Normal.

In the case of supplying large amounts of liquid nitrogen from an equipped large tank when supplying liquid nitrogen in such an apparatus, for example, Japanese Patent Laid-Open No. 3-1075
As described above, by forming a dry N ₂ atmosphere around the supply pipe, condensation on the surface of the supply pipe is prevented, and liquid moisture due to the condensation enters the surrounding devices and causes failure or corrosion. To prevent the cause.

[0005] Unless the above-mentioned large-scale equipment is used, for example, as shown in FIG. 11, a transparent or translucent low-temperature-resistant flexible liquid nitrogen supply pipe 2 is provided in a liquid nitrogen cylinder 1 in which liquid nitrogen is sealed. In general, a device to be cooled 3 such as a cryostat is connected through a liquid crystal display, and a simple device for supplying liquid nitrogen through the liquid nitrogen supply pipe 2 is used.

[0006]

However, the above-mentioned relatively simple apparatus does not need a function for preventing dew condensation, which is a problem in the conventional large-scale equipment, but rather secures the inside of the liquid nitrogen supply pipe 2. Is required to be able to confirm whether or not nitrogen in liquid state is flowing.

This is based on the following reasons. That is, in the simple apparatus as described above, since it is not necessary to always supply liquid nitrogen, the internal temperature of the liquid nitrogen supply pipe 2 reciprocates between normal temperature and liquid nitrogen temperature. If a large amount of liquid nitrogen is suddenly supplied during cooling, a negative thermal shock is given to the device to be cooled 3 and the device to be cooled 3 itself is damaged. On the other hand, if only almost vaporized nitrogen is supplied, the cooling efficiency becomes extremely low. Therefore, in such simple devices, it is extremely important to be able to confirm that an appropriate amount of liquid nitrogen is flowing.

[0008] Usually, the liquefied nitrogen supply pipe 2 arranged in the atmosphere cannot avoid the adhesion of frost to the surface even under a considerably air-conditioned environment. There is a problem that the inside of the pipe 2 cannot be visually recognized, and even if this adhered frost is removed, it is immediately frozen again, so that the inside of the liquid nitrogen supply pipe 2 cannot be visually recognized after all. .

In the prior art disclosed in JP-A-3-1075, the inside of the shielding member disposed around the supply pipe is made to have a dry N ₂ atmosphere. Is effective, but has a problem that even when applied to a simple device, the supply pipe is covered with a shielding member, so that liquid nitrogen cannot be visually recognized.

The present invention has been made in view of the above points, and has as its object to provide an apparatus for visually confirming the state of liquid nitrogen flowing through a liquid nitrogen supply pipe. Is what you do.

[0011]

According to a first aspect of the present invention, there is provided an apparatus for visually confirming the presence of liquid nitrogen, comprising: a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder and a device to be cooled; In the apparatus for visually confirming the state of liquid nitrogen sent to the apparatus to be cooled from the liquid nitrogen cylinder, a pipe having a transparent portion in which the liquid nitrogen is conducted is provided. A main body having a transparent portion corresponding to the transparent portion is provided around the pipe via a heat insulating holding member, and a ventilation member having air permeability is provided in the main body, and introduction of a dry gas into the main body is introduced. A mouth is formed, wherein the mouth is formed.
The invention is characterized in that the pipe is a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder formed of a transparent material and a device to be cooled.

The invention according to claim 3 is characterized in that an airtight space layer is formed between the main body and the pipe, and the invention according to claim 4 is characterized in that the airtight space layer is formed. The present invention according to claim 5 is characterized in that the hermetic space layer is maintained in a reduced pressure state.

According to a sixth aspect of the present invention, there is provided a piping having a transparent portion through which a transparent liquid nitrogen supply pipe for connecting a liquid nitrogen cylinder and a device to be cooled passes.
A heat insulating holding member is interposed between the pipe and the liquid nitrogen supply pipe, and a main body having a transparent portion corresponding to the transparent part of the pipe is provided around the pipe via the heat insulating holding member, An airtight space layer is formed between the airtight space layer and the pipe, and the invention according to claim 7 is characterized in that a dry gas is sealed in the airtight space layer. In addition, the invention according to claim 8 is characterized in that the airtight space layer is maintained in a reduced pressure state.

Further, according to the ninth aspect of the present invention, a pipe having a transparent portion through which liquid nitrogen is conducted is provided, and a transparent portion corresponding to the transparent portion is provided around the pipe via a heat insulating holding member. A main body having a main body, a space between the main body and the pipe is formed in an airtight space layer, and a heater is provided in a transparent portion of the main body.
The invention described in Item 0 is characterized in that the pipe is a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder formed of a material having transparency and a device to be cooled. The invention described in the above is characterized in that a dry gas is sealed in the hermetic space layer, and the invention described in the twelfth aspect is characterized in that the hermetic space layer is maintained in a reduced pressure state. It is assumed that.

[0015]

When liquid nitrogen is supplied from a liquid nitrogen cylinder to a device to be cooled via a liquid nitrogen supply pipe, the liquid nitrogen supply pipe is cooled. Since a ventilation member having air permeability is provided and an inlet for introducing a drying gas is formed inside the main body, the inside of the main body is always filled with the drying gas, and moisture is contained in the atmosphere inside the main body. The frost does not adhere to the surface of the pipe (the transparent liquid nitrogen supply pipe itself in the invention according to claim 2) having the transparent portion through which the liquid nitrogen is located inside the main body and through which the liquid nitrogen is conducted.

Further, since the main body and the pipe are brought into contact with each other via the heat insulating holding member, the main body is cooled by the liquid nitrogen through the pipe (the liquid nitrogen supply pipe in the second aspect of the present invention). Frost does not adhere to the outer peripheral surface of the main body. Therefore, the state of the liquid nitrogen can be reliably visually recognized through the pipe having the transparent portion and the main body having the transparent portion corresponding to the transparent portion.

According to the third aspect of the present invention, since the airtight space layer is formed between the main body and the pipe, it is possible to prevent the moisture in the air from being newly supplied to the inside of the main body. It is possible to prevent frost from adhering to the surface of the pipe. Preferably, a dry gas is sealed in the hermetic space layer (the invention of claim 4), or the hermetic space layer is kept in a reduced pressure state (the invention of claim 5), so that the surface of the pipe is further increased. Can be prevented from adhering to the frost. Furthermore, for prevention of frost adhesion on the main body surface, the above-mentioned claim 1
Thus, the state of the liquid nitrogen can be reliably visually recognized.

According to the sixth aspect of the present invention, a pipe having a transparent portion through which a transparent liquid nitrogen supply pipe penetrates is provided, and a heat insulating holding member is interposed between the pipe and the liquid nitrogen supply pipe. And a main body having a transparent portion corresponding to the transparent portion of the pipe is provided around the pipe via a heat insulating holding member, and an airtight space layer is formed between the main body and the pipe. As in the above invention, the state of liquid nitrogen flowing inside the transparent liquid nitrogen supply pipe can be visually recognized through a pipe having a transparent part and a main body having a transparent part corresponding to the transparent part. ,Preferably,
By enclosing a dry gas in the hermetic space layer (invention of claim 7) or by keeping the hermetic space layer in a reduced pressure state (invention of claim 8), the state of liquid nitrogen can be more reliably visually recognized. It is.

Further, according to the ninth aspect of the present invention, a transparent portion corresponding to the transparent portion is provided around a pipe having a transparent portion (in the invention of the tenth aspect, the transparent liquid nitrogen supply pipe itself) via a heat insulating holding member. A main body having a portion is provided, an airtight space layer is formed between the main body and the pipe, and a heater is provided in the transparent portion of the main body, so that moisture in the air is newly supplied to the inside of the main body. By heating the transparent portion of the main body, the state of liquid nitrogen can be visually recognized, and preferably, a dry gas is sealed in the airtight space layer (the invention of claim 11). Alternatively, by maintaining the airtight space layer in a reduced pressure state (the invention of claim 12), the state of the liquid nitrogen can be more reliably visually recognized.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. FIGS. 1 and 2 show an embodiment of the apparatus for visually recognizing liquid nitrogen according to the present invention. This apparatus 4 is a cylindrical body 5 made of a transparent resin such as acrylic resin.
Both ends of the main body 5 are formed as engaging portions 6 having a small diameter with respect to the central portion. The inner peripheral surface of each engaging portion 6 of the main body 5 is formed in a filter shape and
A cylindrical ventilation member 7 made of a material such as foamed urethane capable of releasing the gas inside the outside to the outside is provided, respectively.
The inner peripheral surface of each of the ventilation members 7 is made of a resin having a low thermal conductivity such as a resin such as polyethylene terephthalate or methacrylic styrene or a fluorine-based rubber. The members 8, 8 are respectively engaged.

On the outer peripheral surface of the main body 5, an inlet 9 for introducing a dry gas such as dry air or nitrogen gas into the main body 5 is formed so as to protrude. The opening 9 has a dry gas supply pipe 11 connected at one end to a dry gas cylinder 10 filled with dry gas.
Is connected.

As shown in FIG. 2, the visual recognition device 4 having the above configuration connects the outlet 12 of the liquid nitrogen cylinder 1 filled with liquid nitrogen to the inlet 13 of the device 3 to be cooled such as a cryostat. For example, a transparent or translucent, low-temperature-resistant, flexible liquid nitrogen supply pipe 2 made of silicon or a fluorine-based resin such as a tetrafluoroethylene-based resin or a perfluoroalkoxy-based resin is attached to an intermediate portion of the pipe. It has been made like that. That is, the liquid nitrogen supply pipe 2 penetrates the inside of the engagement portion 6 of the main body 5 of the visual recognition device 4 and is in close contact with the inside of each of the heat insulating holding members 8. ,
The liquid nitrogen supply pipe 2 is appropriately held inside the visual recognition device 4 and heat transfer from the liquid nitrogen supply pipe 2 to the main body 5 is prevented.

In this embodiment, the main body 5 is used.
Is made of acrylic and the whole is configured as a transparent portion, but a transparent portion is formed by providing a viewing window made of a transparent resin, glass or the like on a metal main body 5 coated with a heat insulating resin. You may. Further, in this embodiment, the transparent liquid nitrogen supply pipe 2 itself penetrates through the inside of the main body 5, but instead of this liquid nitrogen supply pipe 2, it is connected to an intermediate portion of the liquid nitrogen supply pipe 2. A pipe having a transparent portion to be formed may pass through the inside of the main body 5.

Next, the operation of this embodiment will be described.
First, by opening the valve of the dry gas cylinder 10 and supplying the dry gas from the inlet 9 of the main body 5 through the dry gas supply pipe 11, the dry gas is
And the excess dry gas is discharged to the outside through the ventilation member 7.

In this state, when the valve of the liquid nitrogen cylinder 1 is opened and liquid nitrogen is supplied from the outlet 12 through the liquid nitrogen supply pipe 2 to the inlet 13 of the apparatus 3 to be cooled, the liquid nitrogen supply pipe Although the moisture in the air solidifies and frost adheres to the surface of the liquid nitrogen 2 and the inside of the liquid nitrogen supply pipe 2 cannot be visually recognized, in this embodiment, the inside of the main body 5 is filled with dry gas. Since the atmosphere inside the main body 5 does not contain moisture, frost does not adhere to the surface of the liquid nitrogen supply pipe 2 located inside the main body 5.

Further, since the main body 5 and the liquid nitrogen supply pipe 2 are brought into contact with each other via the heat insulating holding member 8 made of a material having low thermal conductivity, the liquid nitrogen supply pipe 2
Is not transmitted to the main body 5, and since the main body 5 is cooled, frost does not adhere to the outer peripheral surface of the main body 5.

Therefore, in this embodiment, the main body 5
Can reliably prevent frost from adhering to the surface of the liquid nitrogen supply pipe 2 located inside the liquid nitrogen supply pipe 2, so that the inside of the liquid nitrogen supply pipe 2 can be reliably visually recognized via the transparent main body 5. it can.

FIGS. 3 to 5 show another embodiment of the present invention. In this embodiment, the visual recognition device 4 comprises:
It has a cylindrical main body 5 made of metal whose surface is coated with a heat-insulating resin, and this main body 5 is divided into two upper and lower parts along the axial direction. A flange 14 protruding in the radial direction is integrally formed on a side edge of the divided portion of the main body 5, and the main body 5 is formed into a cylindrical shape by joining the flange 14 with a bolt 16 via a packing 15. Is formed.

The upper and lower portions of the main body 5 are provided with openings 17 for external visual recognition whose end faces are formed in a planar shape. The external visual opening 17 is made of a transparent material such as glass. The external visual recognition plate 18 is closely contacted with a packing 19 therebetween. Further, an external holding plate 21 having an external viewing window 20 substantially similar to the external visual opening 17 is closely attached to the outside of the external visual opening 18 through the packing 19. The external visibility plate 18 is fixed to the main body 5 by tightening the external holding plate 21 to the main body 5 with the fixing screw 22.
The inside of the main body 5 is sealed via the packings 19.

Inside the engaging portions 6 formed at both ends of the main body 5, a pipe extending through the main body 5 and through which liquid nitrogen is conducted is provided as a heat conductive pipe. Low, made of fluororesin that does not deteriorate at low temperatures, or
A conductive pipe 23 made of stainless steel or the like having a heat insulating resin layer is provided, and an inner surface of the engaging portion 6 and the conductive pipe 23 are provided.
2 made of the material having low thermal conductivity
Two annular heat-insulating holding members 8 are provided.

In the upper and lower portions of the conductive pipe 23, an opening 24 for internal visual recognition having an end surface formed in a planar shape is formed, and the opening 24 for internal visual recognition is made of a transparent material such as glass. The internal visual recognition plate 25 is in close contact with a packing 26. Further, an inner holding plate 28 having an inner viewing window 27 substantially similar to the inner viewing opening 24 is tightly attached to the inner viewing opening 24 outside the inner viewing plate 25 via a packing 26. The internal holding plate 28 is fixed to the conductive pipe 23 by a fixing screw 29 to fix the internal visual recognition plate 25 to the conductive pipe 23, and the conductive pipe 23 is connected via the packings 26.
It is made to seal the inside.

Further, a bush 30 is provided at the end of the engaging portion 6 of the main body 5 so as to be in close contact with the heat insulating holding member 8 located on the outside. A lid 31 is fastened and fixed to the end face so as to press and hold the bush 30 inward of the main body 5.
The main body 5 and the conductive pipe 23 are brought into contact with each other with a very small contact area via the heat insulating holding member 8, and the bush 30 is pressed by fastening and fixing the lid 31. Thus, the heat insulating holding member 8 located on the outside is pressed and adhered to the end of the engaging portion 6 of the main body 5, thereby holding the inside of the main body 5 in an airtight state. Further, in this embodiment, the inside of the main body 5 is sucked by a vacuum pump (not shown) connected to the suction port 5a as necessary, and is kept in a reduced pressure state.

In this embodiment, with the heat insulating holding members 8 attached to the outer periphery of the conductive pipe 23, the divided main bodies 5 are joined so that the flanges 14 thereof come into contact with each other via the packing 15. The visual recognition device 4 is formed by fastening the lid 31 to both ends of the main body 5 via the bush 30.

In the visual recognition device 4, a liquid nitrogen supply pipe connected to an outlet of a liquid nitrogen cylinder (not shown) and a liquid nitrogen supply pipe connected to an inlet of a device to be cooled are connected to the conducting pipe 23, respectively. Thereby, it is mounted between the liquid nitrogen cylinder and the device to be cooled.

When liquid nitrogen is supplied through the liquid nitrogen supply pipe, the conducting pipe 23 is cooled by the liquid nitrogen. In this embodiment, the inside of the main body 5 is airtight and It is kept in a decompressed state, and by preventing the moisture in the air from being newly supplied to the inside of the main body 5, the atmosphere inside the main body 5 hardly contains moisture, so that the main body 5 There is no frost adhering to the surface of the conductive pipe 23 located in the inside. Moreover, while maintaining the inside of the main body 5 in a reduced pressure state,
Since the main body 5 and the conductive pipe 23 are brought into contact with each other via the heat insulating holding member 8 made of a material having low thermal conductivity, the temperature of the conductive pipe 23 is not transmitted to the main body 5. By cooling the main body 5,
Frost does not adhere to the outer peripheral surface of the main body 5.

Therefore, in this embodiment, as in the previous embodiment, the conductive pipe 23 located inside the main body 5 is also used.
Frost can be reliably prevented from adhering to the surface of the inside of the conductive pipe 23 through the external visual recognition plate 18 of the external visual opening 17 and the internal visual recognition plate 25 of the internal visual opening 24. The state of liquid nitrogen can be visually recognized with certainty.

The inside of the main body 5 is kept airtight,
Even if dry air is sealed in the inside, the state of the liquid nitrogen inside the conducting pipe 23 can be reliably visually recognized. In some cases, the temperature of the conducting pipe 23 is transmitted to the main body 5. In this case, the main body 5 can be prevented from cooling by forming fins or the like on the surface of the main body 5.

Further, as described above, the inside of the main body 5 is not kept in a reduced pressure state, or the inside of the main body 5 is not sealed with the dry gas.
The state of the liquid nitrogen flowing inside the conducting pipe 23 can be sufficiently visually recognized.

FIG. 6 shows another embodiment of the present invention. In this embodiment, the heat insulating holding member 8 is provided inside the conductive pipe 23 according to the embodiment shown in FIGS. , The transparent liquid nitrogen supply pipe 2 is held therethrough, and the other configuration is the same as that of the above-mentioned embodiment. .

In this embodiment, the visual recognition device 4 is mounted in the middle of the liquid nitrogen supply pipe 2 that connects the liquid nitrogen cylinder and the device to be cooled. Even when liquid nitrogen is supplied, the inside of the main body 5 is kept airtight and decompressed, the atmosphere inside the main body 5 contains almost no moisture, and Since the nitrogen supply pipe 2 is brought into contact with the heat-insulating holding member 8, the conduction pipe 23 is not cooled by the temperature of the liquid nitrogen supply pipe 2, and the conduction pipe 23 is located inside the main body 5. Frost does not adhere to the surface of the pipe 23. Further, since the main body 5 and the conductive pipe 23 are brought into contact with each other via the heat insulating holding member 8, the temperature of the conductive pipe 23 is not transmitted to the main body 5, and the main body 5 is cooled. This prevents frost from adhering to the outer peripheral surface of the main body 5.

When the liquid nitrogen supply pipe 2 is held inside the conductive pipe 23 via the heat insulating holding member 8, the transparent liquid nitrogen supply pipe visually recognized through the external visual recognition plate 18 and the internal visual recognition plate 25. A small space 32 hermetically sealed by the heat insulating holding member 8 is formed around the periphery of the space 2, but the volume of the space 32 is extremely limited.
Since the amount of water contained in the liquid nitrogen supply pipe 2 is extremely small, frost does not adhere to the liquid nitrogen supply pipe 2 so much as to hinder the visual recognition through the external visual recognition plate 18 and the internal visual recognition plate 25.

Therefore, in this embodiment, similarly to the above-described embodiment, the external visual recognition plate 18 of the external visual opening 17 is provided.
In addition, the state of the liquid nitrogen in the liquid nitrogen supply pipe 2 penetrating through the inside of the conductive pipe 23 through the internal visual check plate 25 of the internal visual opening 24 can be surely visually recognized.

7 to 9 show another embodiment of the present invention. In this embodiment, as in the embodiment shown in FIGS. An opening 17 for external visual recognition is perforated in the upper and lower portions, and an external visual recognition plate 18 and an external pressing plate 21 are closely connected to the external visual opening 17 via packings 19, respectively. Further, in the present embodiment, a resistance heating type metal heater 33 is embedded inside the external visual recognition plate 18, and the heater 33 is heated via a lead wire 34. A controller 35 for adjusting the temperature is connected. Then, the engaging portion 6 of the main body 5
Inside, a transparent liquid nitrogen supply pipe 2 is provided via a heat insulating holding member 8, and the other parts are the same as those in the above embodiment.

In this embodiment, when liquid nitrogen is supplied through the liquid nitrogen supply pipe 2, the liquid nitrogen supply pipe 2 is cooled by the liquid nitrogen, but is contained inside the main body 5. There is not much moisture from the beginning,
Since the inside of the main body 5 is airtight,
Since no new water is replenished over time, no frost adheres to the surface of the liquid nitrogen supply pipe 2. Further, by cooling the liquid nitrogen supply pipe 2,
Although the external visual recognition plate 18 is also gradually cooled,
By heating the heater 33 to a predetermined temperature by the controller 35 via the lead wire 34 to heat the external visual recognition plate 18 to a predetermined temperature, frost adheres to the surface of the external visual recognition plate 18. There is no end.

Therefore, in this embodiment, as in the previous embodiment, the liquid nitrogen supply pipe 2 located inside the main body 5 is also provided.
Also, since it is possible to reliably prevent frost from adhering to the surface of the external visual recognition plate 18, the external visual recognition opening 17 is prevented.
The state of the liquid nitrogen inside the liquid nitrogen supply pipe 2 can be reliably visually recognized through the external visual recognition plate 18.

In the above-described embodiment, the visual recognition device 4 is mounted in the middle of the liquid nitrogen supply pipe 2. However, as shown in FIG.
Alternatively, the visual recognition device 4 may be stably held at any one of the inlets 13 of the device to be cooled.

In the above embodiment, the main body 5
The liquid nitrogen supply pipe 2 itself penetrates the inside of the main body 5, but instead of the liquid nitrogen supply pipe 2, a pipe having a transparent portion connected to the middle of the liquid nitrogen supply pipe 2 is provided in the main body 5. You may make it penetrate inside.

Further, in the above embodiment, the inside of the main body 5 is kept airtight.
If the inside of the main body 5 is maintained in a reduced pressure state, or if the inside of the main body 5 is filled with a dry gas, the state inside the liquid nitrogen supply pipe 2 can be more reliably visually recognized.

In the above embodiment, the heater 33 is buried inside the external visual recognition plate 18.
The heater 33 may be attached to the surface of the external visual recognition plate 18.

[0050]

As described above, according to the first aspect of the present invention, in the liquid nitrogen visual recognition device according to the present invention, the main body is provided with a gas permeable member and the inside of the main body is provided. Since the introduction port for introducing the drying gas is formed, the inside of the main body is always filled with the drying gas, the atmosphere inside the main body does not contain moisture, and the liquid nitrogen located inside the main body is conducted. Since frost does not adhere to the surface of the pipe having the transparent portion, and the main body and the pipe are brought into contact with each other via the heat insulating holding member, the main body is cooled via the pipe by liquid nitrogen. No frost adheres to the outer peripheral surface of the main body. for that reason,
The state of the liquid nitrogen can be reliably visually confirmed through the pipe having the transparent portion and the main body having the transparent portion corresponding to the transparent portion.

According to the third aspect of the present invention, since the airtight space layer is formed between the main body and the pipe, it is possible to prevent the moisture in the air from being newly supplied to the inside of the main body. It is possible to prevent frost from adhering to the surface of the piping inside the main body, and it is more preferable to seal dry gas in the hermetic space layer or to keep the hermetic space layer in a reduced pressure state. It is possible to prevent frost from adhering to the surface of the piping, and also to prevent frost from adhering to the body surface.
This is the same as the first aspect of the present invention, whereby the state of liquid nitrogen can be visually recognized with certainty.

According to the invention of claim 6, a pipe having a transparent portion through which a transparent liquid nitrogen supply pipe penetrates is provided, and a heat insulating holding member is interposed between the pipe and the liquid nitrogen supply pipe. And a main body having a transparent portion corresponding to the transparent portion of the pipe is provided around the pipe via a heat insulating holding member, and an airtight space layer is formed between the main body and the pipe. Frost can be prevented from adhering to the surface of the main body and the piping inside the main body, and the inside of the transparent liquid nitrogen supply pipe can be prevented through the piping having the transparent part and the main body having the transparent part corresponding to the transparent part. The state of the flowing liquid nitrogen can be visually recognized, and preferably, the state of the liquid nitrogen can be more reliably visually recognized by sealing the dry gas in the hermetic space layer or maintaining the hermetic space layer in a reduced pressure state. .

Further, according to the ninth aspect of the present invention, a main body having a transparent portion corresponding to the transparent portion is provided around the pipe having the transparent portion via a heat insulating holding member, and a space between the main body and the pipe is provided. Since the heater is disposed in the transparent portion of the main body while being formed in the airtight space layer, it is possible to prevent moisture in the air from being newly supplied to the inside of the main body and to heat the transparent portion of the main body. Thereby, the state of the liquid nitrogen can be visually recognized, and preferably, the state of the liquid nitrogen is more reliably maintained by sealing the dry gas in the hermetic space layer or maintaining the hermetic space layer in a reduced pressure state. Can be visually recognized.

Therefore, according to the present invention, the state of the liquid nitrogen flowing inside the pipe inside the main body can be reliably visually recognized, so that the flow rate of the liquid nitrogen can be appropriately adjusted. The maintenance of expensive measuring machines at low temperature can be achieved, and the transfer process of liquid nitrogen can be completed in a proper time.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing one embodiment of a device for visually confirming liquid nitrogen according to the present invention.

FIG. 2 is a configuration diagram showing a mounted state of the visual recognition device of FIG. 1;

FIG. 3 is a longitudinal sectional view showing another embodiment of the present invention.

FIG. 4 is a side sectional view taken along line AA of FIG. 3;

FIG. 5 is a plan view of FIG. 3;

FIG. 6 is a longitudinal sectional view showing another embodiment of the present invention.

FIG. 7 is a longitudinal sectional view showing another embodiment of the present invention.

FIG. 8 is a side sectional view taken along line BB of FIG. 7;

FIG. 9 is a plan view of FIG. 7;

FIG. 10 is a longitudinal sectional view showing another embodiment of the present invention.

FIG. 11 is a configuration diagram showing a conventional liquid nitrogen supply device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Liquid nitrogen cylinder 2 Liquid nitrogen supply pipe 3 Device to be cooled 4 Viewing device 5 Main body 7 Ventilation member 8 Insulation holding member 9 Inlet 10 Dry gas cylinder 11 Dry gas supply pipe 14 Flange 17 External viewing opening 18 External viewing plate 21 External holding Plate 23 Conductive piping 24 Internal viewing opening 25 Internal viewing plate 28 Internal holding plate 31 Lid 33 Heater

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) F25D 3/10 B67D 5/38 F17D 3/00

Claims (12)

(57) [Claims] 1. A liquid which is disposed in a middle portion of a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder and a device to be cooled, and which visually confirms a state of liquid nitrogen sent from the liquid nitrogen cylinder to the device to be cooled. In the apparatus for visually confirming nitrogen, a pipe having a transparent section through which the liquid nitrogen is conducted is provided, and a main body having a transparent section corresponding to the transparent section is provided around the pipe via a heat insulating holding member. A gas-permeable member having a gas-permeable property, and an inlet for introducing a dry gas is formed inside the main body. 2. The apparatus for visually confirming liquid nitrogen according to claim 1, wherein said pipe is a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder formed of a transparent material and a device to be cooled. 3. A liquid which is disposed in a middle portion of a liquid nitrogen supply pipe connecting the liquid nitrogen cylinder and the device to be cooled, and which is used to visually check a state of liquid nitrogen sent from the liquid nitrogen cylinder to the device to be cooled. In the apparatus for visually confirming nitrogen, a pipe having a transparent section through which the liquid nitrogen is conducted is provided, and a main body having a transparent section corresponding to the transparent section is provided around the pipe via a heat insulating holding member. A liquid nitrogen visual recognition device, wherein an airtight space layer is formed between the pipe and the pipe. 4. The visual recognition device for liquid nitrogen according to claim 3, wherein a dry gas is sealed in an airtight space layer between the main body and the pipe. 5. The visual recognition device for liquid nitrogen according to claim 3, wherein an airtight space layer between the main body and the pipe is maintained in a reduced pressure state. 6. A liquid disposed in a middle portion of a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder and a device to be cooled, for visually checking a state of liquid nitrogen sent from the liquid nitrogen cylinder to the device to be cooled. In the apparatus for visually confirming nitrogen, a transparent liquid nitrogen supply pipe connecting the liquid nitrogen cylinder and the device to be cooled is provided with a pipe having a transparent portion penetrating therethrough, and between the pipe and the liquid nitrogen supply pipe. A heat insulating holding member is provided, and a main body having a transparent portion corresponding to the transparent portion of the pipe is provided around the pipe via the heat insulating holding member, and an airtight space layer is formed between the main body and the pipe. A visual recognition device for liquid nitrogen. 7. The visual recognition device for liquid nitrogen according to claim 6, wherein a dry gas is sealed in an airtight space layer between the main body and the pipe. 8. The visual recognition device for liquid nitrogen according to claim 6, wherein an airtight space layer between the main body and the pipe is maintained in a reduced pressure state. 9. A liquid which is disposed in a middle part of a liquid nitrogen supply pipe connecting the liquid nitrogen cylinder and the device to be cooled, and which is used to visually check a state of the liquid nitrogen sent from the liquid nitrogen cylinder to the device to be cooled. In the apparatus for visually confirming nitrogen, a pipe having a transparent section through which the liquid nitrogen is conducted is provided, and a main body having a transparent section corresponding to the transparent section is provided around the pipe via a heat insulating holding member. A liquid nitrogen visual recognition device, wherein an airtight space layer is formed between the fluid nitrogen and the pipe, and a heater is provided in a transparent portion of the main body. 10. The apparatus for visually confirming liquid nitrogen according to claim 9, wherein said pipe is a liquid nitrogen supply pipe connecting a liquid nitrogen cylinder formed of a transparent material and a device to be cooled. 11. The visual recognition device for liquid nitrogen according to claim 9, wherein a dry gas is sealed in an airtight space layer between the main body and the pipe. 12. The apparatus for visually confirming liquid nitrogen according to claim 9, wherein an airtight space layer between the main body and the pipe is maintained in a reduced pressure state.