NL8303856A - RADIATION DEVICE. - Google Patents

Description

τ * · V Μ Η3Ν 10,827 1 N.V. Philips' Incandescent light factories in Eindhoven.

"Irradiation Device". ------

The invention relates to an irradiation device for emitting ultraviolet radiation with at least a wavelength greater than 315 nm, which device comprises at least in a plane parallel tubular low-pressure discharge lamps extending on either side of a syranny plane extending in the direction of the longitudinal axes of the lamps, but perpendicular to the plane through said lamps, wherein the inner wall of the discharge vessel of the lamps is provided with a layer which reflects the ultraviolet radiation reflecting over a part of the tube circumference of 10, the discharge vessel is present, a radiation exit window being formed in the lamp. Such a device is known from Dutch patent application 7710575 laid open to public inspection.

This irradiation device is used for photochemical or photobiological purposes, for example as a sun bed, sun canopy or sun wound, as a facial irradiator and the like, for direct pigmentation of the skin (bmining transmitter erythema worming) or in the phototherapy of skin diseases. The body is exposed to long-wave ultraviolet radiation (UV-A radiation) for some time.

In the above NL-publication, a radiation chamber for phototherapy is described, in which an irradiation space is at least partly feared by a wall in which a large number of vertically placed UV-A radiation-emitting, tubular low-pressure mercury vapor discharge lamps are present. The wall is composed of a number of flat parts which make an obtuse angle with respect to each other.

For example, the free area within the chamber is formed by a regular hexagon. It is also possible to subject radiation to both body parts located on the side as well as on the front or rear. Such a device is bulky and has a complicated construction. This is a drawback, particularly when using relatively small spaces.

The object of the invention is to provide an irradiation device which has small dimensions and a simple construction, wherein a body can be irradiated on a number of sides at the same time.

According to the invention, the irradiation device of the type mentioned in the preamble is characterized in that the radiation emission windows of at least the lamps furthest from the symmetry plane are inclined towards that symmetry plane. Oblique is here understood to mean that the lamp in question assumes a position such that the main direction of the radiation emerging from the exit window encloses an acute angle with the plane of symmetry. In a practical embodiment, this angle for a lamp located furthest from the symmetry plane is approximately 35 °.

The food irradiation device according to the invention has small dimensions. The device has the advantage that a person can be irradiated from several sides at the same time, avoiding a complicated construction of the housing in which the lamps are placed. The use of specially shaped external reflectors in the housing, such as those present in some known devices, in particular behind at least the lamps closest to the outside of the housing, is avoided.

In a radiation device according to the invention, the longitudinal axes of the lamps are preferably located in a flat plane. With such an arrangement of the lamps, the housing can be manufactured in a simple manner and few additional provisions are necessary, for example for a person lying on the abdomen also to expose the lateral body parts to radiation.

In a preferred embodiment of the device according to the invention, at least more than four lamps are present in the housing, the inclination of the radiation emission window of a lamp relative to the plane of symmetry being smaller as the distance from said lamp to that plane decreases. In this way a homogeneous radiation intensity is obtained on the body to be irradiated. This embodiment also has the advantage that the use of a special parabolic reflector behind the radiation sources in order to obtain a concentrated beam can be omitted, particularly in the case of sunlamps or facial irradiators. Also, adapting the shape of the house for this purpose is not necessary.

In a special embodiment of the device according to the invention, the mutual distance of the lamps which are located far from the plane of symmetry is smaller than the mutual distance of the lairpins located near the plane of symmetry. The lateral body parts can then also be subjected to intense radiation.

The invention will be further elucidated with reference to the drawing. Herein: figure 1 schematically shows an embodiment of the irradiation device according to the invention in perspective? figure 2 shows a cross-section of the irradiation device according to figure 1 in plane II-II.

The irradiation device designed as a sunbed for emitting ultraviolet radiation according to figure 1 comprises a rectangular housing 1, which comprises a number of walls arranged perpendicularly to each other. The top of the housing is provided with a cover plate 2, which is permeable to ultraviolet radiation with a wavelength greater than 315 nm (UV-A radiation). This radiation is generated by a dozen tubular low-pressure mercury transponder charge lamps running parallel to each other in a flat plane. These are indicated with 3.

On the inner wall of the tubular discharge vessel of the lair pin there is a reflecting layer (for example lamp 3a-indicated just 4a), which layer extends over only part of the circumference (eg 180 to 240 °) (see fig. 2). Over the remaining part of the extraction as well as over the said reflecting layer, a luminescent layer is present (not visible in the drawing) which converts the resonance radiation of 254 nm generated in the mercury discharge into ultra-25 violet radiation with a wavelength greater than 315 nm. In the reflecting layer, a radiation emission window (e.g. 5a) is formed, i.e. that part of the extraction which is free from said reflecting material. The ultraviolet radiation exits the housing via plate 2.

The tubular discharge lamps 3 are located on either side 3Q of a synchronization surface 6 extending in the direction of the longitudinal axes of said lair pin (see Fig. 2). The radiation emission window (5a, 5b, 5c) of the said lairpin is turned obliquely to the syimetry plane, which is visible in Fig. 2. The lairpin is rotated slightly about their longitudinal axis. The lamps which are most distant from the plane of symmetry (3a and 3j) have a radiation emission window which has a slanting position than the lairpins more close to the plane of symmetry, such as 3b and 3c.

The tilt of an exit window can be characterized 8303858 t 'PHN 10.827 4 by the dotted lines 7a, 7b, 7c which represent the principal direction of the radiation emitted by a lamp (3a, 3b, etc.). To illustrate this, a line (7a) is shown which makes an angle of approximately 35 ° with the symmetry plane 6. The other lines enclose a sharper angle, the smaller the distance to the symmetry plane 6 is.

As can be seen from Fig. 2, the body parts of a person present on the cover plate 2 of a person lying on the stomach or back can also be irradiated on the side.

In the shown embodiment, a radiation device 10 according to the invention is shown, which serves as a sunbed. However, house 1 can just as well serve as solar heaven. In an alternative, the house has a slightly curved shape. The irradiation lamps are so positioned relative to each other that the longitudinal axes are then located in a slightly curved plane. In another embodiment, there is no glass plate on the radiation exit side of the housing.

In a practical embodiment of a radiation device according to the invention shown in Fig. 1, the housing has a length of approximately 2 m, a height of approximately 15 cm and a width of approximately 60 cm. The length of the tubular discharge lamps is approximately 1.80 m 2o (power approximately 100 W, external diameter approximately 38 irm). A reflective layer consisting of aluminum oxide is present on the inner wall of the discharge vessel of these lamps about 200 ° from the circumference of the tube. This leaves a radiation emission window of 160 °, which is free from that reflecting material. Furthermore, a luminescent layer is present over the entire circumference, which converts the resonance radiation of mercury into UV-A radiation. The luminescent layer is therefore present both at the location of the window and at the reflecting layer. The luminescent layer contains strontium tetraborate activated with divalent europium.

The radiation emitted by this luminescent material has a wavelength of approximately 370 nm.

8303856 35

Claims (4)

1. An irradiating ultraviolet radiation device having at least a wavelength greater than 315 ran, said device comprising at least a plane parallel tubular low-pressure mercury-discharge lamps extending parallel to each other and extending on either side of the axes of the longitudinal axis of the lamps but are located perpendicular to the plane extending through said lamp plane, the inner wall of the discharge vessel of the lamps being provided with an ultraviolet radiation-reflecting layer which is present over a part of the tube attraction of the discharge vessel, wherein in the lamp 10 a the radiation emission window is formed, characterized in that the radiation emission windows of at least the farthest sides of the symmetry plane are inclined towards that plane. Irradiation device according to claim 1, wherein at least four lamps are arranged in the housing, characterized in that, as the distance of a lamp from the plane of symmetry decreases, the inclination of its radiation emission window with respect to that plane is smaller. Irradiation device according to claim 1 or 2, characterized in that the longitudinal axes of the lamps lie in a flat plane. 20 Irradiation device according to claim 1, 2 or 3, characterized in that the mutual distance of the lamps located far from the plane of symmetry is less than the mutual distance of the lamps situated near the plane of symmetry. 25 30 8303856 35