SU642614A1 - Gas caloritmeter - Google Patents

Description

(54) GAS CALORIMETER

Claims (2)

The invention relates to the field of measurement technology and can be used to create systems that measure the energy of light fluxes in the vacuum ultraviolet (VUV) spectral region, in particular, pulsed lamps. Devices are known for absolute measurements of the radiation energy in the ultraviolet region of the spectrum of l based on a comparison of the radiation of the source under investigation with a reference one, which includes radiation detectors, emitting filters, a reference source and a recording receiver. The use of such a device for measurements in the VUV spectral region is complicated by the fact that practically no reference sources exist for this spectral region. Of the known devices, the closest in technical essence to the present invention is a device for measuring the energy of radiation 2, based on the heating of the absorbing gas, containing a chamber filled with a gas or a mixture of gases with a known absorption capacity in the laser spectral range and a recording device. However, the described device is designed to measure the radiation energy of an OGGDUAI parallel light beam and using such a device to measure the energy of flash tubes in the VUV region would require evacuation or blowing of a non-absorbent gas between the lamp and the camera, as well as complex recalculations on the entire radiating surface and in all directions radiation propagation, which would reduce the measurement accuracy. The purpose of the invention is to simplify and accelerate measurements of the radiation energy. The goal is achieved by placing a measuring nozzle with a filter made of porous glass on the side wall of the chamber, and a recording device is installed at the end of the measuring nozzle and also made in the form of a corrugated cylinder of a material that is transparent to radiation, for example, from quartz glass. The drawing shows the conventional scheme of a gas calorimeter, where 1 is the calorimeter chamber, 2 is the measuring nozzle, 3 is a porous glass filter, 4 is a pressure sensor, 5 is a lamp under study. 364 For measurements, the lamp is placed in a hermetically sealed chamber 1 filled with air to atmospheric pressure or another absorbing gas. A part of the radiation of a flash lamp, enclosed between the shortwave boundary n) of the quartz glass opacity (156) and the shortwave radiation oxygen oxygen (180nm) is absorbed and pulses the air in the calorimeter. A differential pressure is created in the chamber, from which the temperature jump is calculated, and the amount of heat received by air from the change in temperature. Since an intense pulsed irradiation of air in the chamber of the calorimeter produces a shock wave and resonant oscillations of the air, the chamber is designed as a corrugated cylinder with a narrow passage to the measuring pat- ter, in which a porous glass filter is installed in front of the membrane pressure sensor. As shown by high-speed imaging of a rubber membrane stretched at the end of the measuring nozzle, with this design of the calorimeter, the membrane smoothly reaches its maximum deflection, and due to low thermal diffusivity during 80 ms, there is no noticeable decrease in the membrane deflection amplitude. This plateau on the pressure pulse curve is suitable for recording the pressure jump and allows using the ideal gas equation to calculate the temperature. The advantages of the proposed device over the existing one are that it provides a direct measurement of the VUV energy of the pulsed lamp during optical pumping of the laser; allows you to measure the energy of the VUV radiation at once across the entire radiating surface of the lamp and at all angles and does not require recalculation of the entire surface, does not require a reference source of VUV radiation. Claim 1. Gaseous calorimeter for measuring the energy of VUV radiation of flash lamps, containing a chamber filled with absorbing gas and a recording device, characterized in that, in order to simplify and accelerate measurements, a measuring nozzle with a filter made of porous glass is placed on the side wall of the chamber. The recording device is installed at the end of the measuring nozzle. 2. A calorimeter according to claim 1, characterized in that the chamber is made in the form of a corrugated cylinder of a material that is transparent to radiation, a calorimeter not absorbed by the gaseous medium, for example, of quartz glass. Sources of information taken into account prior expertise. 1. US patent W 3366789, CL 347847, 1971. 2. Authors certificate of the USSR 347847, cl. H 01 S 3/00, 1971.