RU53772U1 - INFRARED RADIATION RECEIVER (OPTIONS) - Google Patents

Abstract

The proposed utility model relates to photosensitive devices designed to detect thermal radiation, in particular, to cooled semiconductor receivers of infrared (IR) radiation.

The technical result when using the proposed utility model is to reduce the time the device reaches the required temperature range.

The indicated technical result in the first embodiment of the proposed device is achieved by the fact that in the IR radiation receiver, which contains a dewar vessel installed in the case and hermetically fixed in the frame and equipped with entrance windows, in the cavity of which is filled with dried gas, a cooled holder with a crystal with photosensitive placed on it elements (PSE), moreover, a heat-insulating material is located around the holder, a diaphragm is installed, made of heat-insulating material in the form of a cylindrical Coy sleeve adjacent to the inner wall of the dewar. In the second embodiment, in the IR radiation receiver, in addition, an optical filter plate is fixed on the diaphragm with a gap from the input window, and the heat-insulating material located around the holder is divided into two layers, one of which is adjacent to the holder, the other to the inner wall of the Dewar vessel, between which are passed electrical leads coming from a chip with PSE to an external signal processing unit.

When using a sleeve made of heat-insulating material as a diaphragm, there will be a decrease in heat gain to the elements being cooled and an actual decrease in the mass to be cooled, and the presence of an optical filter plate mounted on the diaphragm with a gap from the entrance window, and the placement of electrical leads between layers of heat-insulating material due to thermal insulation reduces heat gain.

Description

The proposed utility model relates to photosensitive devices designed to detect thermal radiation, in particular, to cooled semiconductor receivers of infrared (IR) radiation.

A known infrared radiation receiver, comprising an evacuated Dewar vessel mounted in a frame mounted in a frame, is provided with input windows, opposite which there is a crystal with photosensitive elements (PSE) and a diaphragm on the cooled holder, and the sealed cavity formed by the holder, Dewar vessel and the frame is filled with dried gas (see certificate for utility model of the Russian Federation No. 14666, MKI 7 G 01 J 5/02, 2000). This design has a significant time to enter the regime when cooling to an operating temperature of ~ 77 K, due to convective heat transfer inside the gas-filled cavity, due to which unintentional cooling of the inner wall of the Dewar vessel occurs, i.e., an actual increase in the mass to be cooled.

A known infrared radiation receiver comprising a vacuum mounted Dewar vessel mounted in a frame and provided with external and internal entrance windows, inside which a cooled holder is mounted with a crystal with photosensitive elements located on it, the cavity around the holder is filled with heat-insulating material, and the diaphragm is installed between the external and internal input the windows of the Dewar vessel (see Pat. for the invention of the Russian Federation No. 2194254, MKI 7 G 01 J 5/02, 2002). In this design, the cooled mass and heat gain are reduced due to the withdrawal of the cooled diaphragm into the vacuum cavity and the introduction

thermal insulation material, however, there is complexity and high complexity in the manufacture of the receiver.

The closest in technical essence to both versions of the proposed designs of the IR radiation receiver is known, containing a Dewar vessel installed in the case and hermetically fixed in the frame with entrance windows, in the cavity of which is filled with dried gas a cooled holder with a crystal placed on it with photosensitive elements and diaphragm, and around the holder are insulating material. Electrical leads adjacent to the holder were drawn from the crystal with the PSE to the external signal processing unit (see CD BJAI.433426.005 Matrix technologies photodetector. Matrix Technologies, 2002). However, at the same time, the cooled mass and heat inflows are also large, which arise due to convection transfer inside the cavity filled with an inert gas in the Dewar vessel and the heat capacity of the electrical leads, which leads to an increase in the time the device reaches the operating temperature regime.

The technical result of the proposed utility model is to reduce the time it takes for the device to reach the required temperature.

The indicated technical result in the first embodiment of the proposed device is achieved by the fact that in the IR radiation receiver, which contains a dewar vessel installed in the case and hermetically fixed in the frame and equipped with entrance windows, in the cavity of which is filled with dried gas, a cooled holder with a crystal with photosensitive placed on it elements, with a heat-insulating material located around the holder, a diaphragm made of heat-insulating material in the form of a cylindrical Tulku, adjacent to the inner wall of the dewar.

The specified technical result in the second embodiment of the proposed device is achieved by the fact that in the infrared radiation receiver, which contains a dewar vessel installed in the housing and hermetically fixed in the frame and equipped with entrance windows, in the cavity of which is filled with dried gas, there is a cooled holder with a photosensitive crystal placed on it elements equipped with electrical leads, installed a diaphragm made of heat-insulating material in the form adjacent to the inner wall of the vessel South of the cylindrical sleeve, on which an optical filter plate is fixed with a gap from the input window, and around the holder there are two layers of heat-insulating material, one of which is adjacent to the holder, the other to the inner wall of the Dewar vessel, and electrical leads are missing between them.

New in the first version of the receiver is that the diaphragm is made in the form of a cylindrical sleeve of heat-insulating material adjacent to the inner wall of the Dewar vessel.

New in the second version of the receiver is that the diaphragm is made of heat-insulating material in the form of a cylindrical sleeve adjacent to the inner wall of the Dewar vessel, on which an optical filter plate is fixed with a gap from the inlet window, and the heat-insulating material around the holder is made in two layers, one of which adjacent to the holder, the other to the inner wall of the Dewar vessel, with electrical leads missing between them.

When using a sleeve made of a heat-insulating material as a diaphragm, there will be an additional decrease in heat gain to the elements to be cooled and an actual decrease in the mass to be cooled, since in this case they will be caused not by convective heat transfer, but by the thermal conductivity of the dried gas - thermal insulation material, which is mainly determined by the thermal conductivity of the dried gas . Therefore, additional winnings will be received.

in time of reaching the required temperature regime. The role of the cooled diaphragm will be played by the inner surface of the sleeve, the temperature of which is always equal to the temperature of the cooled gas.

The implementation of the diaphragm in the form of a sleeve of heat-insulating material adjacent to the inner wall of the Dewar vessel reduces the convective heat transfer that occurs in the gas-filled cavity from the walls of the Dewar vessel to the cooled holder and the crystal, in addition, compared with the prototype, in which the diaphragm is mounted on a cooled holder and made of heat-conducting material, part of the mass to be cooled due to convective heat transfer is practically eliminated. The presence of an optical filter plate mounted on the diaphragm with a gap from the input window is also an insulator of convective heat influx from the input window, which further reduces heat loss. The implementation of the heat-insulating material around the holder in two layers, one of which is adjacent to the cooled holder, the other to the inner wall of the Dewar vessel and the placement of electrical leads between them can also reduce heat gain due to the thermal insulation of the terminals from the cooled holder.

At the same time, the total cooled mass and heat inflows, the load on the cooling system and, ultimately, the time to reach the specified temperature mode are reduced.

The essence of the utility model is illustrated by the drawings: Figures 1 and 2 show the 1st and 2nd variants of the proposed device, respectively.

In the first embodiment, the infrared radiation receiver includes a dewar 3 installed in the housing 1 and sealed in the frame 2, provided with inlet windows 4. In the cavity of the dewar 3 filled with dried gas, there is a cooled holder 5 with a crystal 6 with photosensitive elements placed on it . A diaphragm 7, made in the form of a diaphragm 7, is adjacent to the inner wall of the Dewar vessel at a level from crystal 6 with PSE to the input window 4

bushings made of insulating material. From the holder 5 to the inner wall of the vessel Gyara is a heat-insulating material 8.

In the second embodiment, the infrared radiation receiver comprises a Dewar vessel 3 installed in the housing 1 and sealed in the frame 2, provided with inlet windows 4. In the cavity of the Dewar vessel 3 filled with dried gas, there is a cooled holder 5 with a crystal 6 with photosensitive elements placed on it equipped with electrical leads 9. The diaphragm 7, made in the form of a sleeve of heat-insulating material, is adjacent to the inner wall of the Dewar vessel at the level from the crystal 6 with PSE to the input window 4. An optical filter plate 10 is attached to the inner surface of the sleeve 7 with a gap from the input window. Around the holder 5 are two layers of heat-insulating material 8, one of which is adjacent to the holder, the other to the inner wall of the Dewar vessel, and electrical leads 9 are passed between them.

As a heat-insulating material, for example, a space heat-shielding material (TZMK-10) TU-596-117-86, which is made on the basis of quartz fiber, and has a low thermal conductivity of 0.05 W / micron, high porosity (~ 95 %) and the gray factor in the infrared wavelength range of at least 0.98.

During the operation of the device, the crystal is cooled to cryogenic temperatures. In the proposed designs, the heat capacity of the cooled diaphragm is reduced, the inner surface of the Dewar vessel is practically insulated, the heat influx through the electrical leads is significantly reduced, and, accordingly, the total heat gain and the cooled mass of the device are reduced. This allows you to reduce the load on the cooling system and reduce the time the device reaches the operating temperature mode.

The proposed design was developed for infrared detectors with PSE matrices made of platinum silicide. The glass Dewar vessel with sapphire windows is hermetically welded to a metal frame, which is also hermetically attached to the holder. A crystal with a PSE matrix is mounted on a cooled cylindrical holder, the diaphragm is fixed to the inner wall of the Dewar vessel with glue and made of TZMK material in the form of a cylindrical sleeve with an internal 14 mm and an external 16.5 mm diameters. In the second embodiment, the inner bore of the sleeve is stepped and has a diameter of 15 mm at a length of 0.5 mm from the inlet window, and an optical filter plate made of germanium with a thickness of 0.3 mm is installed on the formed step, while the gap from the inlet window is 0.2 mm The cavity of the Dewar vessel is filled with dried nitrogen, and TZMK brand insulation material is located around the holder, divided into two layers in the second embodiment, between which electrical leads are passed from the crystal with the PSE to the external signal processing unit.

The developed design made it possible to reduce the heat gain of the radiation receiver by 2 times from 0.5 W to 0.25 W, the total cooled mass by 40% from 10 g to 6 g, the time to reach the temperature regime of ~ 77 K for 4 min (~ 60%) .

Claims (1)

1. An infrared radiation receiver, comprising a Dewar vessel installed in the housing and hermetically sealed in a frame provided with entrance windows, in the cavity of which is filled with dried gas, there is a cooled holder with a crystal placed on it with photosensitive elements and a diaphragm made of heat-insulating material in the form of a cylindrical bushings adjacent to the inner wall of the Dewar vessel, with heat-insulating material around the holder. 2. An infrared radiation receiver comprising a Dewar vessel installed in the housing and hermetically fixed in a frame, equipped with entrance windows, in the cavity of which is filled with dried gas, there is a cooled holder with a crystal placed on it with photosensitive elements equipped with electrical leads, and a diaphragm made of heat-insulating material in the form of a cylindrical sleeve adjacent to the inner wall of the Dewar vessel, on which an optical plate is fixed with a gap from the input window iltra, and around the holder there are two layers of heat-insulating material, one of which is adjacent to the holder,
the other is to the inner wall of the Dewar vessel, and electrical leads are missing between them.