SU1227908A1 - Radiation plant - Google Patents

Description

This invention relates to lighting engineering, in particular to irradiation installations.

The aim of the invention is to increase the concentration of radiant energy.

The drawing shows the irradiation installation.

The irradiation unit includes an extended source E with a length of 2f located along the optical axis of the concentrating reflector 2 of round-symmetric or cylindrical shape. At a distance h from the center of the radiation source 1, the irradiation zone 3 is located along the optical axis of the device.

To obtain the maximum concentration of radiant energy in the irradiation zone, it is necessary for each element of the reflector surface to create a radiation beam whose center coincides with the center of the irradiation zone, which corresponds to ensuring that the reflected beam bisectrix passes through the center of the irradiation zone.

To determine the equation describing the specified reflector profile, one can use the well-known differential equation of the profile curve of an axisymmetric reflector, which has the form

3 -tg6

where dy and dx-profile increments along the corresponding coordinate axes;

b - the angle between the normal to the surface element and the axis of the reflector.

From the drawing it is clear that o. f- | - a

where f and a are the angles characterizing the bisectrixes of the incident and reflected beams, respectively. In turn, the incident beam (φ) can be expressed in terms of the angles ФЗ and а4, which limit the incident n from the source. choke rays

V3

J - 2

By expressing the angles Φ; f4 and its coordinates X, at the current point M, the distance h between the centers of the source and the irradiation zone, and the length of the source 21, we obtain the desired differential equation for the reflector profile with the specified properties.

- | | , 25 (arctg - + arctg- +

+ 2arctg-)

The specified property of the reflector (symmetrization of the reflected beam of rays) can be extended to the irradiator of the projector type. Known searchlights have parabolic reflectors, creating asymmetrical reflected beams. For this, the irradiator profile 2 is constructed in such a way that the bisectrons of the reflected beams are directed along the optical axis of the irradiator. The equation for such a profile is easy to obtain from

h-00.

The obtained differential equations can be solved by any known methods with the given parameters of the irradiating installation: h - scatter from the center of the source to the center of the irradiation zone, 21 - the length of the radiation source; Ho; Uo - coordinates of any point of the reflector, for example, its dimensions.

Claims (3)

(54 (1. RADIATION INSTALLATION, comprising an irradiation zone, a reflector and an extended radiation source located along the optical axis of the reflector, characterized in that, in order to increase the concentration of radiant energy while maintaining the dimensions, the reflector has a profile d described by the equation tg [0 , 25 (arctg ^ - + arctgy - ^ + 2arctg ^)] where x, y are the coordinates of the profile points; [is the length of the radiation source; h is the distance from the center of the radiation source to the center of the irradiation zone. 2. Installation according to π. 1. characterized in that the reflector has a round-symmetrical shape. 3. Installation according to π. 1, characterized in that the reflector has a cylindrical shape.