DE9413076U1 - Treatment light emitting polarized light for manual operation - Google Patents

Description

Treatment lamp emitting polarized light

for manual operation

The invention relates to a treatment lamp that emits polarized light for biostimulation with polarized light. In particular, the invention relates to a treatment lamp that emits polarized light with a certain intensity and wavelength and covers a certain surface area.

DE-PS 32 20 218 describes the general biostimulating effect of polarized light. Figure 5 of this reference in particular shows a treatment lamp in which a polarization filter is used. The lamp is suitable for generating a light beam with a diameter of about 55 mm and the lamp power is 150 W. The treatment lamp generates a lot of heat and is cooled by a fan. A lot of power is lost in the form of heat and the efficiency is relatively low, which also causes serious cooling problems. In addition, the handling of this lamp is not optimized while achieving optimal cooling and optimal efficiency.

It is an object of the invention to create such a treatment lamp in which, on the one hand, a construction for favorable handling is created and, on the other hand, an optimal function, for example with regard to cooling, can be achieved.

This is achieved according to the invention by the features in claim 1.

In particular, the use of the Brewster polarizer with the mirror sandwich made of float glass panes lying directly on top of each other achieves a high polarizer efficiency, while on the other hand the mirror sandwich made of float glass panes can be easily cooled.

is realized because, for example, there are no insulating air gaps between the individual glass panes.

Furthermore, the fact that the float glass panes lie directly on top of one another prevents the polarizer from becoming dirty due to dust particles penetrating between the float glass panes. This results in the lamp having a longer service life.

According to an advantageous development of the invention, the light filter plate closes the second hollow cylinder. This closes the second hollow cylinder so that it is transparent to light, but at the same time it is mechanically sealed against the ingress of dust. Accordingly, the reflector closes the first hollow cylinder by means of a seal, whereby the entire tube device consisting of the first and second hollow cylinders is hermetically sealed and thus protected from contamination.

According to another advantageous development, the light source arrangement is arranged in the middle and front part in such a way that the space around the light source arrangement is larger near the polarizer than near the reflector. This results in an optimal cooling air flow.

According to an advantageous embodiment, the first angle is between 105° and 120°.

According to an advantageous further development, the handle is provided on its outer surface with recesses for receiving the fingers

on the side facing away from the light exit opening of the front part. This allows the treatment light to be held optimally and aimed at the area to be treated, for example the face of the person using the device. 35

It is advantageous to have the slots on the handle at the bottom of the handle. This means that the escaping cooling air flow does not pose an obstruction.

According to an advantageous development of the invention, the float glass panes have elliptical shapes and the glass carrier has the shape of an elliptical receiving trough with an elliptical base and a wall running around a significant portion of the base, the wall being provided with a plurality of locking lugs which engage in the mirror sandwich and thus hold it in place. Furthermore, the mirror sandwich can lie directly on the cut surface of the tube device, thereby ensuring further hold.

The lamp is advantageously a metal halide lamp assembled with the reflector and is underheated by at least 5% during operation. This results in a longer service life for the lamp. The lamp is particularly advantageously designed so that it emits no or only a negligible amount of ultraviolet light.

The invention is explained below using a preferred embodiment with reference to the drawing. The drawing shows:

Figure 1 shows an embodiment of the treatment lamp according to the invention in longitudinal section;

Figure 2 shows the side view of the treatment light from Figure 1;

Figure 3 the front view of the treatment light from Figure

Figure 4 the front view of the treatment light, diagonally from below;

Figure 5 shows the light source arrangement of the treatment lamp in perspective view;

Figure 6 is an enlarged detail of the Brewster polarizer in section;

Figure 7 is a plan view of the glass carrier; Figure 8 is a side view of the glass carrier;

Figure 9 shows a section indicated by the section line A-A in Figure 7;

Figure 10 is an enlarged view of the

4
Detail designated as "Detail 1".

The treatment lamp 1 shown in Figure 1 consists of three structural parts, ie a housing 2, a light source arrangement 3 and a fan 4. The housing itself consists of a handle 21 _7, a curved middle part 22 and a front part 23, the shape of which can be clearly seen from Figures 1 to 4. The housing 2 is preferably made of two plastic parts which are adapted to one another and which determine the hollow space for receiving the other structural parts.

The light source arrangement 3 is arranged centrally in the middle part and the front part 23 of the housing 2 in the position shown in Figure 1 in such a way that a distance is formed between the inner housing wall and the light source arrangement essentially everywhere. The term "centric" means that this distance is the same on both sides in the direction perpendicular to the plane of the drawing in Figure 1. As can be seen from Figure 1, the light source arrangement 3 is not arranged completely centrally in the plane of the drawing.

The light source arrangement 3 consists of two cylindrical tubes 31, 31 welded together at an obtuse angle, the axes of which are at an angle of approximately 114°, which corresponds to twice the Brewster angle. The two tubes 31, 32 are cut at the outer vertex along a plane in which the intersection point of the tube axis lies, and the elliptical opening thus created is covered by a Brewster polarizer 33. The light source arrangement 3 can be seen in a perspective view in Figure 5.

Figure 6 shows a section of part of the Brewster polarizer 33. The Brewster polarizer 33 consists of a number (e.g. 5) of thin, plane-parallel, elliptical float glass panes 34 arranged one behind the other, which rest directly on one another, i.e. without forming a gap between them. The float glass panes

are enclosed in a glass carrier 35, which is shown only schematically in Figure 6. The float glass panes 34 achieve a high polarizer efficiency, while on the other hand the mirror sandwich made of float glass panes can be easily cooled because they lie directly on top of each other and are not separated from each other by insulating air gaps between the glass panes. The float glass panes are therefore in heat-conducting contact with each other, so that the mirror sandwich can be considered a one-piece component in terms of its heat-conducting properties.

Furthermore, the fact that the float glass panes lie directly on top of one another means that dust particles cannot get between the glass panes. This means that the Brewster polarizer maintains its high level of efficiency even after a long service life.

A more detailed representation of the glass carrier in which the mirror sandwich is enclosed can be seen in Figures 7 to 10. The glass carrier 35 has the shape of an elliptical receiving trough with an elliptical base 39 and a wall 40 running around a significant portion of the base 39. The wall 40 is provided with a plurality of locking lugs 41 which engage laterally in the mirror sandwich (not shown in Figures 7 to 10). The wall 40 does not have to extend around the entire elliptical base 39, so that, for example, the mirror sandwich can be mounted together with the glass carrier 35 close to the tubes 31, 32 without the glass carrier 35 abutting against the housing 2. The float glass panes therefore lie directly on the cut edge surface of the tube device made of tubes 31 and 32, which are cut at the Brewster angle. The float glass panes 34 and the glass carrier 35 are sealed to the cut surface by means of a seal, as are a reflector 36 and a light filter plate 37 to the tubes 31 and 32, as will be explained below. This seals the interior of the tube device made of tubes

31 and 32, so that no dust can penetrate into this interior. At the rear end of the tube 31, a lamp 42, preferably a metal halogen lamp, is arranged with a reflector 36, which is held tightly against an annular axial inner shoulder of the tube 31, with a seal (not shown) preferably being arranged between the annular, axial inner shoulder and the reflector 36.

The lamp 4 2 emits visible and infrared light axially forwards, with the angle of incidence on the Brewster polarizer 33 being 57°. The lamp 4 2 is designed in such a way that it emits almost no ultraviolet light, which must be avoided in view of the risk of burns for the person using it and the undesirable, localized tanning. The lamp output is approximately 20 W, but must not be more than 80 to 100 W, since the cooling conditions are essentially optimal below this limit output.

The float glass plates 34 of the Brewster polarizer 33 reflect the light parallel to the axis of the tube 32, whereby the reflected light is linearly polarized. The non-reflected light components strike the black inner surface of the shutter plate 35 and the resulting heat is dissipated by the cooling air.

The interior of the light source arrangement 3 is closed at the front end of the tube 32 with a yellow light filter plate 37. The purpose of the light filter plate 37 is, on the one hand, to filter out spectral components below about 400 to 450 nm from the light rays reflected at the polarizer 33 and, on the other hand, as already indicated above, to mechanically close the interior of the light source arrangement 3 so that the optical properties of the elements arranged here are not impaired by dust formation.

Laterally in the cooling air flow below the lamp 42 is a

Mounting plate 38 is arranged, which is held by several support elements of the housing 2, not shown in the drawing. The electrical connection line leads to the mounting plate 38, which also carries a fuse and some electrical components. It is expedient if an electrical attenuation element is connected in series with the lamp 42 so that the lamp 42 is underheated by about 2 to 5%. Underheating the lamp 42 increases its service life on the one hand and shifts the spectral distribution of the emitted light towards the infrared range on the other (by reducing the effective light temperature), which increases the penetration depth of the rays. It is also possible that such a spectral distribution is more favorable for biostimulation. Reducing the light temperature also reduces the power consumption. Underheating the lamp 42 can also be achieved by reducing the supply voltage. For example, if the nominal voltage of the lamp is 12 V, the transformer supplying the lamp can be designed to deliver about 11 - 11.4 V.

The fan 4 is aligned in the axial direction in the handle 21 axially opposite to the lamp 42 and sucks the air into the housing interior through the inlet opening 24 (Figure 3) formed around the light source arrangement 3. The air flows out via slots (Figures 1 and 4) at the free end of the handle 21. The cooling air flows in the housing interior along the entire surface of the light source arrangement 3. This flow is illustrated by arrows in Figure 1.

The shape of the housing shown in the drawing is not only aesthetically pleasing, but it also leads to very good cooling. Behind the closure plate 33 and in the area of the upper end of the tube 31, the volume of the interior of the housing is the largest due to the curvature of the middle part of the housing and the flow speed is sufficient to transfer the heat from the large surface of the closure plate 33.

to be removed; then the interior space in the area of the lamp 35 is reduced, whereby the air speed is increased considerably. In this channel 26, the air flows quickly over the parabolic surface of the reflector with the lamp 42, whereby intensive cooling takes place here and the operating temperature of the lamp 42 does not exceed the permitted values. The temperature of the housing is not more than 20 ⁰ C higher than the ambient temperature even after long operation of the lamp.

The axis of the handle 21 is slightly inclined to the lamp axis in such a way that the direction of the light rays emerging from the treatment lamp 1 emerges at an angle of between 105 and 120°, preferably 105 and 110° to the handle axis. This alignment enables a very comfortable posture and a comfortable light treatment.

In the case of a metal halide lamp with 20 W power and a reflector diameter of 50 mm, the inner diameter of the tubes 31, 32 is also chosen to be 50 mm. This treatment lamp emits parallel, polarized light in a circular beam with a diameter of 50 mm and the light power density is about 50 mW/cm ² .

Claims (8)

• · · *·* · *► ·*· ·4*• ········9Claims 1. Treatment lamp emitting polarized light, with a housing (2), a handle (21) formed in one piece with the housing (2), a lamp (42) with a maximum electrical power of 100 W mounted in the housing (2), a reflector (36) arranged directly behind the lamp (42), a polarizer (33) arranged in the light beam of the light emitted by the lamp (42), a light filter plate (37) for filtering out the ultraviolet spectral components of the emitted light, and a fan (4) arranged in the housing (2) behind the reflector (36), characterized in that the polarizer is a Brewster polarizer which is composed of a mirror sandwich made of a plurality of thin, plane-parallel float glass panes which lie directly and congruently on top of one another and are enclosed in a glass carrier (35), the housing (2) has three consecutive and directly adjacent adjoining parts which define a common interior space, the first part being the essentially tubular handle (21) with an axis, the second part being a curved central part (22) connected at one end to one end of the handle (21), and the third part being a cylindrical front part (23) connected to another end of the central part, that the front part (23) has an axis which encloses a first obtuse angle with the axis of the handle (21), that a light source arrangement (3) with a closed interior space is arranged in the interior of the housing (2) at a distance from the inner walls of the same in such a way that an air passage channel (26) is formed around this light source arrangement (3), that the light source arrangement has a pair of interconnected hollow cylinders (31, 32) with axes which enclose a second obtuse angle which is twice as large as the Brewster angle is that the hollow cylinders are cut by a surface between whose normal and the two axes the Brewster angle is included, that the lamp (42) and the reflector (36) with the first hollow cylinder (31), that the Brewster polarizer (33) is mounted inside the light source arrangement (3) and deflects part of the light emanating from the lamp (42) towards the second hollow cylinder (32), and that the fan (4) is arranged inside the handle (21) to suck fresh air through the channel (26) formed around the entire surface of the light source arrangement, wherein the handle (21) has slots (25) for letting the air out of the interior.
10 2. Treatment lamp according to claim 1, characterized in that the light filter plate (37) closes off the second hollow cylinder (32). 3. Treatment lamp according to claim 1 ₇ , characterized in that the light source arrangement (3) is arranged in the middle and the front part (22, 23) such that the space around the light source arrangement is larger in the vicinity of the polarizer (33) and narrower in the vicinity of the reflector (36). 4. Treatment light according to claim 1, characterized in that the first angle is between 105° and 120°. 5. Treatment light according to claim 1, characterized in that the handle has indentations on its outer surface for receiving the fingers on its side facing away from the light exit opening of the front part (23). 6. Treatment lamp according to claim 5, characterized in that the slots (25) of the handle (21) are provided at the lower end thereof. 7. Treatment lamp according to claim 1, characterized in that the float glass panes (24) have elliptical shapes and the glass carrier (35) has the shape of an elliptical receiving trough with an elliptical base and a wall running around a substantial portion of this base, wherein the wall is provided with a plurality of locking lugs which engage in the mirror sandwich and thus hold it in place. 8. Treatment light according to claim 2, characterized in that the lamp (42) is a metal halide lamp assembled with the reflector (36) and is underheated by at least 5% during operation.