RU2152665C1 - Method for production of light pulse and pulse light source - Google Patents

Abstract

FIELD: production of short-term high-power light signals with wide spectrum, in particular, high-speed photography, photometry. SUBSTANCE: transparent wall, which is located on trajectory of emitting shock wave in gas, is used simultaneously for increasing of brightness temperature in reflected wave and for pulse clipping due to fast mixing of gas heated by shock wave with cold products produced by wall destruction. EFFECT: decreased light pulse duration, increased maximal brightness temperature. 2 cl, 1 dwg

Description

 The invention relates to technical physics, and more specifically to fields of technology that use short powerful light pulses of a wide spectral range (for example, when modeling phenomena accompanied by a bright flash, in high-speed photography and high-frequency spark cinematography).

 Analogs and their criticism.

 A known method of obtaining a light pulse (I.S. Marshak. Pulse light sources. M., Energy, 1978), including the use of a working gas limited by a transparent wall, an electric discharge in a gas that creates a shock wave (HC), ionizing the working gas and the most causing its glow.

 The method is implemented using gas discharge lamps (I.S. Marshak. Pulse light sources. M., Energy, 1978), consisting of two main current-carrying electrodes, a gas gap between them and a sealed transparent cylinder filled with a chemically inactive gas.

 A pulsed discharge in the lamp is powered by some electrical source capable of providing a large current in a short time.

 The disadvantages of the analogue are that the maximum brightness temperatures in the assortment of modern serial flash lamps (I.S. Marshak. Pulse light sources. M., Energy, 1978) do not exceed 15-17 kK when it is impossible to obtain a light pulse of duration τ ≤ 1 μs. When a certain limit is reached, a further increase in the discharge energy does not lead to an increase in brightness with an increase in the total light pulse. Due to the rapid decrease in pressure in a diverging shock wave in a gas, the peak brightness at the time of discharge is weakened and, in general, the light pulse is insufficient in both brightness and duration to solve a large class of high-speed photography tasks.

 The prototype and its criticism.

 A known method of obtaining a light pulse (I.Sh. Model. Measurement of brightness temperatures in shock waves. // ZhETF, 1957. T. 4, 32, 714), including the creation of a layer of the working gas, limiting it with a massive gas-dynamic piston on one side and massive a transparent barrier on the other hand, and the creation in the working gas of a flat hydrocarbon ionizing the working gas and causing it to glow.

 The method is implemented using a device (I.Sh. Model. Measurement of brightness temperatures in shock waves. // ZhETF, 1957. T. 4, 32, 714), consisting of a shock generator, including an explosive charge (explosive) (acting as a gas-dynamic piston); the channel (chamber) following it, the cavity of which is filled with working gas and is limited by a transparent plug (barrier).

 After the explosive is detonated, the expanding detonation products are a piston, which creates a strong emitting hydrocarbon in the working gas.

 The disadvantage of the prototype is the relatively low peak brightness temperature implemented in this method. Due to the relatively large mass of explosives and, as a consequence, the large mass of explosion products, the duration of a light pulse is relatively long (the duration of a light pulse τ in this method is determined by the time of pressure drop in the products of explosives due to unloading, and these times are at least an order of magnitude higher than those which are required in high-speed photography tasks).

 SUMMARY OF THE INVENTION

 Reducing the duration of the light pulse will expand the class of problems solved by high-speed photography. In particular, reducing the duration of the light pulse while maintaining the exposure value will increase the resolution of images in photographs and record the spectra of the flow around extended bodies moving at high speeds (for example, on open ballistic paths).

 The technical result consists in the fact that the proposed method and device can reduce the duration of the light pulse with increasing peak brightness temperature.

 The technical result is achieved by the fact that in the method of obtaining a light pulse, including the creation of a working gas layer bounded by a piston and a transparent barrier, and generation of a shock wave ionizing the working gas in the working gas, the light pulse is cut off by mixing the heated working gas with the degradation products of the transparent barrier and with piston material.

где T₂ - температура в отраженной УВ, T₁ - температура за фронтом исходной УВ, γ - показатель адиабаты), обеспечивая пик яркости излучателя. Происходит деструкция преграды, которая теряет прозрачность и перемешивается с горячим газом, и одновременно происходит перемешивание рабочего газа с материалом поршня, обеспечивая отсечку светового импульса.When the piston moves in the working gas, a shock wave is excited. As the layer of shock-compressed gas propagates, the optical thickness of the emitter increases as a result of ionization of the working gas. The shock wave front in a gas emits like a black body at a given temperature, starting with an optical thickness of approximately three. At a distance L from the piston, which approximately corresponds for a given piston speed and a given type of gas and its initial parameters to a set of optical thickness ≈3, a transparent barrier is established. Upon reaching the shock wave in a shock-compressed gas, a reflected wave is excited, behind which the temperature rises sharply (

where T ₂ is the temperature in the reflected shock wave, T ₁ is the temperature behind the front of the initial shock wave, γ is the adiabatic index), providing a peak in the brightness of the emitter. The destruction of the barrier occurs, which loses its transparency and mixes with the hot gas, and at the same time the working gas is mixed with the piston material, providing a cutoff of the light pulse.

 A device for implementing this method (pulsed light source) contains a chamber with a closed cavity with a working gas, bordering the piston of a shock wave generator, ionizing the working gas, and on the other hand, with a transparent barrier.

The technical result is achieved due to the fact that the mass of the transparent barrier is selected on the order of the mass of the working gas; Thanks to this choice of the ratios between the masses of the barrier and the working gas, effective mixing and cooling of the working gas (and quenching of its radiation) are achieved and, at the same time, the occurrence of backlighting is prevented (due to the glow of the surrounding gas). The background illumination produced by the radial or axial expansion of the piston elements outside the closed volume is cut off either by using a relatively small mass of the piston (when the pressure decrease in the piston elements outside the closed chamber immediately leads to the generation of shock wave amplitudes in the environment at which ionization is not realized) , or due to the use of a medium with a high first ionization potential, for example, CO ₂ , as an ambient gas.

 The mixing of a thin layer of a barrier with a working gas results from the instability of a thin layer of a heavier material located in a lighter gas and moving with acceleration (E. Ott. Nonlinear Evolution of the Rayleigh-Taylor Instability of a Thin Layer. Phys. Rev. Lett. V 29, 1972, p. 1429).

 As a piston, for example, a thin explosive layer or an electrically blown thin metal layer can be selected (V. A. Burtsev, I. V. Kaloshin, A. V. Luchinsky. Electrical explosion of conductors and its use in electrophysical installations. M. , Energoatomizdat, 1990). As a transparent barrier, for example, a polymer film or a thin layer of glass can be used.

 The short duration of the pulse rise and the fast cutoff of peak intensity are carried out with comparable masses (of the order) of the transparent barrier and the working gas (here the term "order" is determined in accordance with the source (Polytechnical Dictionary, Moscow, Sovetskaya Encyclopedia, 1989, p. 406)).

 The drawing shows a device with which experimentally shown the feasibility of the method, where 1 is a hydrocarbon generator; 2 - the piston; 3 - camera; 4 - working gas; 5 - a transparent barrier. Arrows indicate the direction of light emission.

 Information confirming the possibility of achieving a technical result.

 The device includes a piston 2 of the generator HC 1, for example, a layer of explosives, which at the initial moment of time explodes, exciting in the working gas 4, for example argon, enclosed in a closed cavity of the chamber 3, a one-dimensional radiating HC. The working gas 4, on the other hand, is limited by a transparent barrier 5, for example a polymer film, the mass of which is comparable to the mass of the working gas.

 The method is implemented as follows.

 The movement of the piston 2 at the initial moment of time excites a one-dimensional emitting HC in the created layer of the working gas 4, enclosed in the cavity of the chamber 3 between the piston 2 and the barrier 5. During the interaction of the incident hydrocarbon with a transparent barrier 5, an intensively emitting reflected HC is formed; as a result, a powerful pulse of light arises, passing through a transparent barrier 5 and illuminating the object under study. Under the influence of pressure in the reflected HC, a thin transparent barrier (denser than the working gas) moves with acceleration and, due to the Rayleigh-Taylor instability, mixes with the working gas. Mixing the degradation products of the barrier 5 and the material of the piston 2 with the hot working gas 4 leads to a sharp decrease in its temperature and cutoff radiation.

 The implementation of the method using a piston - a thin layer of explosives initiated on the surface, showed its effectiveness.

Using the proposed method and device based on it was achieved brightness T≈17 MCD / cm ² light source with a duration of t≈1 μs; for comparison, you can specify similar indicators for a standard source: 0.7 Mcd / cm ² , t≈25 μs. A comparison of the quality of photographs obtained using standard gas-discharge IFC lamps and a device that implements this method showed that the proposed method can significantly increase the resolution, and therefore, the information content.

 Thus, the proposed method allows one to obtain the same exposures as in the case of standard sources, but for shorter times (τ ≤ 1 μs), at which blurring of the image of recorded bodies moving with supersonic speeds is not observed.

Claims (2)

 1. The method of obtaining a light pulse, which consists in the fact that in the layer of the working gas, limited on one side by a transparent barrier, and on the other hand, by a thin layer of explosive or an electric explosive thin layer of metal, create a shock wave that ionizes the working gas, different the fact that they cut off the light pulse by destroying the transparent barrier with the loss of its transparency and mixing the heated working gas with the products of the destruction of the transparent barrier and the products of the explosion layer th substance or a thin metal layer.  2. A pulsed light source, including a chamber with a closed cavity with a working gas, bordering on one side with a shock wave generator that ionizes the working gas, and on the other hand with a transparent barrier, characterized in that the mass of the transparent barrier is of the order of the mass of the working gas.