SU997137A1 - Metal-halogen lamp - Google Patents

Description

The invention relates to high-pressure gas discharge lamps, more specifically to metal halide lamps used in solar radiation simulation systems.

 Metallohalide lamps (MGL) are known with predominantly continuous molecules with pnm radiation in the UV, visible and IR spectral ranges close to the spectrum of the Sun. These lamps include MGL with the addition of aluminum chloride (1, which has acceptable spectral characteristics for solar radiation simulators), however, due to the high aggressiveness of the vapor of the halide used, the lamp life does not exceed several tens of hours, which excludes the possibility of their practical use.

For imitation of radiation from the atmospheric Sun in the visible and IR regions (400-1200 nm), MGL with the addition of iodide and tin bromide 2 are used.

However, their. the disadvantage is the incomplete filling of the solar spectrum in the near infrared region. This deficiency is eliminated by IPH with a combination of additives consisting of tin bromide and. tin iodides and cesium 3.

However, the production technology of these MGLs is quite complicated due to the small amounts of cesium iodide introduced into the burner and the need to accurately control the burner geometry.

The lack of both of these types of MGLs is a significant deviation of the radiation spectrum from the sun in the UV-IQ region (nm), which limits

the field of application of these MGLs can also lead to unacceptable errors of ICI operating in all or, especially, in the UV region of the Sun's radiation.

15 The closest to the invention is MGL, containing quartz gogo. a reel filled with mercury, argon and tin iodide 4.

The disadvantage of the known lamp is that it does not provide

radiation spectrum close to solar.

The purpose of the invention is the approach of the radiation spectrum to the solar

25 all spectral regions of its optical radiation.

To achieve this goal in a metal halide lampe containing a quartz burner filled with mercury,

30 argon and tin iodide, tin iodide

introduced in 1 quantity of 0.3 to 1.6 mg / cm of the burner volume.

The drawing shows the spectral characteristic of the lamp.

The dependence of the spectral characteristics of molecular discharge (Nd + SnJ) having a complex layered structure on the burner diameter D., according to which the value (ha) decreases with increasing diameter D, experimentally established, providing the best imitation of the solar spectrum, and D. 18 mm (14,)

1.3 + 0.3 mg / cm, and at D, j 40 mm (iti) bpT 0 ± Ofl mg / cm.

The high degree of quality of the direct imitation of the solar spectrum of the proposed MGL is evident from the data in the table and the drawings.

In laboratory ICIs with an irradiated area of S 224 cm, one MGL is used with a power of 700 W with the addition of 15: tin iodide. The technical characteristics of the lamp are as follows: operating current b A

The voltage on the lamp is 130 V, the external diameter is D. 25 mm, the discharge volume is 18 cm, the filling is argon with a pressure P 15 mm Hg. Art., mercury 3.6 mg / cm tin iodide - 0.7 mg / cm, P 300 mm Hg. Art. In the irradiated technological area, ICI, depending on the characteristics of the optical system, is created in the region of 200-1200, an irradiance of E 0.2-0.27 W / cm, which corresponds to 1.5-2.0 Solar constant EQ). This creates the necessary safety factor for E in the ICI, allows you to extend the useful life of the lamp, conduct accelerated testing of samples, simulate the effects of radiation from certain spectral regions, etc.

Tests show that the proposed MGL is the optimal source for the development and testing of new, more up-to-date photoconverters with increased efficiency and an expanded (300-1200 nm) spectral sensitivity region.

Claims (1)

MGL with the addition of A1C1, MGL with the addition of SnJ The invention The metal halide lamp containing a quartz burner filled with mercury, argon and tin iodide, in order to bring the radiation spectrum to the solar in all spectral 6b fins of its optical and. As a result, tin iodide is introduced in an amount equal to 0.3 to 1.6 mg / cm of the burner volume. Sources of information taken into account in the examination 20-30 12 1. The patent of the Federal Republic of Germany 1539516, cl. H 01 J 61/18, 1972..:. 2. Molodtsov S.N., Prikubets L, B., Bukhanov Yu.A. Lamp-simulator of solar radiation in the visible and infrared spectral regions. Sat Electrical industry, ser. Lighting products, vol. 1/37, 1976. 3. The author's certificate of the USSR 1 661651, cl. H 01 J 61/18, 1977. 4. US Patent 3,927,343, cl. 313-214, 1975. TOO XO ffOD 500 & 7 U (U 600 Hg- SnTs- & tBra SOO / 000 JIOO