JPS62182558A - Joule-thomson cooling device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a Joule-Thomson cooling device, and in particular,
The present invention relates to a Joule-Thomson cooling device that includes a control means that detects the temperature of a cooling section and controls the flow rate of high-pressure injection gas, and utilizes a reduction in ambient temperature based on adiabatic expansion of gas (Joule-Thomson effect).

[Conventional technology]

Conventionally, this type of cooling device uses a bellows mechanism filled with high-pressure gas as a temperature detection means for setting a cooling part to a predetermined cooling temperature. Then, the spring mechanism operates according to the pressure change inside the bellows, which changes depending on the temperature.
This drives the means for adjusting the injection amount of the high-pressure cooling gas, so that the gas injection amount is adjusted.

FIG. 2 shows a conventional example in which a Joule-Thomson cooling device is implemented for an infrared detector.

The conventional example shown in FIG. 2 includes a cylindrical vacuum dewar 20 that has a bottomed hole in the center that communicates with the outside air and a vacuum section that has a U-shaped cross section overall, and It includes an infrared detection element 30 installed on the vacuum side, and a Joule-Thomson cooling device 40 disposed in the center of the vacuum dewar 20 to cool the infrared detection element 30.

The Joule-Thomson cooling device 40 shown in FIG.
High-pressure gas injection unit 4 installed close to the infrared detection element 30
2, a gas adjustment valve 43 that adjusts the amount of gas injected from this high-pressure gas injection part 42, a metal drive ring 44 and a spring mechanism 45 that drive this gas adjustment valve 43, and this spring mechanism 4.
5 and a bellows mechanism 46 that presses the drive rod 44 to the left in the figure.
It is equipped with

Then, the filter 5 is connected to the gas inlet pipe 50 on the right side of FIG.
1, the high pressure gas such as nitrogen or argon is introduced into the cylindrical bellows storage body 4 that houses the bellows mechanism 46.
7, moves to the left while rotating in a spiral while being guided by the central support pipe 48 and the spiral thin tube 49 surrounding it, is injected from the high pressure gas injection part 42, expands adiabatically, and spreads around the surroundings. significantly lowers the temperature. As a result, the location where the infrared detection element 30 is installed is cooled from the back side thereof.

Vacuum dewar 20 in the part facing the infrared detection element 30
is equipped with an infrared transmitting member 21 made of sapphire or the like. A and B indicate high pressure gas flow paths.

[Problem that the invention seeks to solve]

However, in the above conventional example, since the temperature of the cooling section is configured to be transmitted to the bellows mechanism 46 via the metal drive ring 44, temperature changes in the cooling section are not quickly transmitted to the bellows mechanism 46. This is an inconvenience. Then, the overcooling or temperature rise that occurs due to the delay in temperature detection of the cooling section is temporarily left unattended, and as a result, temperature changes in the cooling section and inside the bellows mechanism 46 become large, and temperature control becomes unstable. In addition, there was a drawback that gas consumption increased.

[Purpose of the invention]

Particularly, an object of the present invention is to provide a Joule-Thomson cooling device that can improve the disadvantages of the conventional example and effectively cool the object to be cooled continuously after stable temperature control. shall be.

[Means for solving problems]

The Joule-Thomson cooling device according to the present invention includes a high-pressure gas injection section, a gas adjustment valve that adjusts the gas injection amount of the high-pressure gas injection section, and a gas adjustment valve that is driven in response to the ambient temperature of the high-pressure gas injection section. and regulating valve drive control means for controlling the control valve. The regulating valve drive control means includes a bellows mechanism in which high-pressure gas is sealed, a spring mechanism equipped to resist the pressing operation of this bellows mechanism, and a driving adjustment of the opening degree of the gas regulating valve along with the expansion and contraction of this spring mechanism. It is composed of a driving rod and a driving rod. The drive rod is formed of a hollow member, and the inside thereof is configured to communicate with the inside of the bellows mechanism.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to FIG.

Here, the same reference numerals are used for the same constituent members as in the conventional example described above.

The embodiment shown in FIG. 1 shows the case where the present invention is implemented in an infrared detector. In order to stabilize the operation of the infrared detection element, which is a heat load, this infrared detector
The temperature is maintained at around 00°C.

The embodiment shown in FIG. 1 includes a cylindrical vacuum dewar 20 having a bottomed hole communicating with the outside air in the center and a vacuum part having a U-shaped cross section as a whole, and this vacuum dewar.
20, there is an infrared detection element 30 arranged and equipped as shown in the figure in the same way as in the conventional example described above, and this infrared detection element 3.
The vacuum dewar 20 is provided with a Joule-Thomson cooling device 1 disposed inside a bottomed hole in the center of the vacuum dewar 20 to cool the vacuum dewar 20.

The Joule-Thomson cooling device 1 shown in FIG.
2, a gas adjustment valve 43 that adjusts the amount of gas injected from this high-pressure gas injection part 42, a drive rod 2 and a spring mechanism 45 that drive this gas adjustment valve 43, and a It has a bellows mechanism 3 that presses to the left in Figure 1, and a spring constant adjusting means 4 that is abutted on the right side of the bellows mechanism 3 in the Figure via a slide base [4A]. Among these, the bellows mechanism 3, drive ring 2, and spring mechanism 45 form the main part of the regulating valve drive control device 1o.

High pressure gas is sealed inside the bellows mechanism 3. Due to the action of this sealed high-pressure gas, the entire bellows mechanism 3 expands and contracts as the temperature changes.

The bellows mechanism 3 and the spring mechanism 45 are detachably installed in the cylindrical bellows storage body 5. Splash constant adjustment means 4
The bellows mechanism 3 takes the form of a pressing mechanism to apply compressive force to the bellows mechanism 3, and is installed at the right end of the bellows storage body 5 in FIG. 1 so as to be adjustable from the outside.

Then, remove the filter 5 from the gas introduction pipe 5o on the right side of FIG.
High-pressure gas such as gas or argon introduced through the bellows housing 5 is guided through the central support tube 48 that houses the bellows housing 5 and the spiral thin tube 49 surrounding it, and spirally flows to the left. The gas is injected from the high-pressure gas injection part 42 and expands adiabatically, cooling the surrounding atmosphere. The gas regulating valve 43 is adjusted so that this cooling temperature is about -200°C.

A threaded portion is provided around the gas regulating valve 43A, and is screwed and supported by the valve support member 43A. The gas adjustment valve 43 is further disposed such that its tip faces the gas injection port of the high-pressure gas injection section 42 .

The valve support member 43A is fixed to the drive ring 2.

The drive ring 2 is made of a metal tubular member, and the inside thereof is communicated with the inside of the bellows mechanism 3. 2A is sealed.

Shows the stopper. The left end of the bellows mechanism 3 in FIG. 1 is made up of a pressing plate 3A, and the driving ring 2 is fixed to this pressing plate 3A. Press play) 3A has drive ring 2
A spring mechanism 45 disposed around the is in contact with the spring mechanism 45 . The position of the drive ring 2 and the gas regulating valve 43 integrated therein is specified by the balance between the pressing force of the spring mechanism 45 and the pressing force of the hollow mechanism 3.

The high-pressure gas B injected from the high-pressure gas injection part 42 expands adiabatically to cool the surrounding area, and is then sent out to the right in FIG. 1 along the drive ring 2.

A cylindrical flow path restriction cap 6 is provided to surround the high pressure gas injection section 42.

A squeeze member 7 is provided at the center of the outer periphery of the drive ring 2 inside the flow path restriction cap 6 .

As a result, the gas or liquefied liquid cooled by adiabatic expansion flows along the drive ring 2 and is removed to the outside. As a result, the bellows mechanism 3 directly detects the cold air in the cooling section through the high-pressure gas sealed in the drive ring 2, so that the temperature of the bellows mechanism 3 can be detected accurately and quickly.

The spring constant adjusting means 4 is provided at the right end of the bellows mechanism 3 in FIG. The spring constant adjusting means 4 functions to change the spring constant of the spring mechanism 45 by one apparent value by appropriately compressing the bellows mechanism 3. The spring constant adjusting means 4 is formed by a female screw formed in the cylindrical bellows storage body 5 and a male screw screwed into the female screw, and is easily accessible from the outside through a through hole 9A of the open lid 9, which will be described later. It is adjustable. This spring 9 constant number adjusting means 4 is adjusted in a direction to pre-compress the hollow mechanism 3 when the temperature of the cooling section is set lower. On the other hand, if it is not necessary to set the temperature of the cooling part so low, the amount of compression of the bellows mechanism 3 is adjusted to be smaller.

Continuous fins 49A are provided around the thin tube 49 to effectively pre-cool the thin tube 49 itself with cold exhaust gas. Further, a system member 49B for efficiently receiving precooling by cold exhaust gas and for matching the vacuum dewar 20 and the thin tube 49 is wound around the thin tube 49 and around the continuous fin 49A, respectively. Further, the right end portion of the center support tube 48 in FIG. 1 is equipped with an open lid 9 for fixedly supporting the gas introduction tube 50 and for appropriately discharging the gas sent inside. A through hole 9A for a spring constant adjustment screw is provided in the center of the open lid 9. The other configurations are the same as the conventional example described above.

Next, the operation of each part during temperature control in the above embodiment will be explained.

In order to maintain the ambient temperature of the 30 infrared sensing elements at a predetermined temperature (for example, -200° C.), a certain amount of high pressure gas is normally injected from the high pressure gas injection section 42. On the other hand, when the temperature of the infrared sensing element 30 and its surroundings increases due to the infrared sensing operation of the infrared sensing element 30, the high pressure gas inside the bellows mechanism 3 expands, and the spring mechanism 45
And the drive ring 2 is pushed to the left in FIG. As a result,
The gas adjustment valve 43 is moved far away from the high pressure gas injection section 42, and the amount of high pressure gas injected increases.

Therefore, the ambient temperature receives more of the cooling effect due to the adiabatic expansion of the gas, and the temperature decreases to a preset temperature or lower. Next, this temperature change is immediately detected by the high pressure gas in the bellows mechanism 3 via the high pressure gas in the drive ring 2, causing the bellows mechanism 3 to contract, and at the same time, the pressing force of the spring mechanism 45 causes the drive ring 2 to move to the first position. Move to the right side of the diagram. As a result, the gas regulating valve 43
The gas injection port is moved in the direction of closing, the amount of high-pressure gas injected is reduced, and excessive cooling of the ambient temperature is effectively prevented.

In addition, although the above embodiment specifically exemplified the case where it was implemented for an infrared detector, the present invention is not necessarily limited to this, and can be applied as it is to all other devices that require cooling. .

〔Effect of the invention〕

As described above, the present invention has a structure in which the high-pressure gas sealed in the bellows mechanism is integrally sealed in the drive pipe, so that the temperature detection of the bellows mechanism can be performed accurately and quickly. The amount of high-pressure gas injection can be adjusted with high precision, and the range of temperature fluctuations in the cooling section can therefore be reduced, thereby reducing the consumption of gas used for adiabatic expansion. No superior Joule Thomson cooling system can be provided.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing a case where an embodiment of the Joule-Thomson cooling device according to the present invention is used in an infrared detector, and FIG.
The figure is a sectional view showing a conventional example. 2... Drive ring, 3... Bellows mechanism, 1
0... Regulating valve drive control means, 42...
High pressure gas injection section, 43...Gas adjustment valve.

Claims (1)

[Claims] (1) A high-pressure gas injection section, a gas adjustment valve that adjusts the gas injection amount of the high-pressure gas injection section, and an adjustment valve drive that controls the gas adjustment valve in response to the ambient temperature of the high-pressure gas injection section. In the Joule-Thomson cooling device, the regulating valve drive control means includes a bellows mechanism in which high-pressure gas is sealed, a spring mechanism equipped to resist the pressing operation of the bellows mechanism, and the spring mechanism. and a drive rod that drives and adjusts the opening degree of the gas regulating valve along with the expansion and contraction movement of the valve, and the drive rod is formed of a hollow member, and the inside of the drive rod is communicated with the inside of the bellows mechanism. Joule Thomson cooling device.