SI9520010A - Therapeutical lamp - Google Patents

Abstract

A therapeutical lamp is disclosed for biostimulation with polarised light. The object of the invention is to develop such a therapeutical lamp with a design that on the one hand makes it easy to handle and on the other hand allows an optimum operation, for example as far as cooling is concerned. This object is achieved by the design of the lamp housing (3, 4), the design and mounting of the Brewster polariser (5), including the glass frame (6), by a special arrangement of ring transformer (19), reflector (17) and ventilator (10), and by a special cooling air guidance.

Description

The therapeutic lamp

The invention relates to a therapeutic lamp for biostimulation with polarized light. The invention relates in detail to a therapeutic lamp that emits polarized light of a certain intensity and a certain wavelength, covering a certain surface area.

DE-PS 32 20 218 describes the general biostimulation effect of polarized light. In particular, Figure 5 shows in this file a therapeutic lamp using a polarizing ski filter. The lamp is suitable for generating a beam of some 50 mm in diameter and the power of the lamp is 150 W. The lamp produces a lot of heat and is cooled by a fan. For many applications, it is advisable to irradiate surfaces with a larger cross-section of 100 cm ² to 300 cm ² , which would have to increase the lamp power six times, thus causing serious cooling problems and problems with the convenience of the lamp due to electrical installation. , which would be heavy because of the power required.

It is an object of the invention to create such a therapeutic lamp, in which on the one hand it creates a structure for favorable handling and on the other hand achieves the best performance, e.g. in terms of cooling.

This is achieved by the invention by the features of claim 1.

In detail, using a Brewster polarizer with float glass panels directly adjacent to one another achieves high polarization efficiency, while, on the other hand, the simple cooling of a mirror sandwich made of ground glass panels is achieved, for example. there are no insulating air slots between the glass panes and the glass supports are designed so that the cooling air flow is directed directly through the glass carrier and thus flows through the mirror sandwich.

In addition, direct floating glass panels prevent each other from becoming dirty. In this way, a longer lamp life is achieved.

According to a preferred further embodiment of the invention, the light source is a metal halogen bulb and around the annular transformer is installed the first annular cooling air duct, through which one part of the cooling air flow produced by the fan is directed. Particularly preferably, a second annulus for cooling air is provided between the rear of the reflector and between the annular transformer. This results in not only the cooling air flow directly cooling the Brewster polarizer, but in this way the cooling air flow directly cools all the heat-producing parts, including the reflector and the ring transformer.

Preferably, the annular transformer is directly, heat-conducting, connected to the floor of the therapeutic lamp, which is provided with cooling fins on its inner side facing the interior of the lamp housing, the opening for cooling air being discharged into the lamp housing the area of the outer perimeter of the floorboard near the base of the cooling fins. This design feature makes it possible for the cooling air stream to flow on the one hand to the reflector and the annular transformer and, on the other, to be guided through the cooling fins extending inside the therapeutic lamp housing, thereby achieving further heat dissipation by means of the floor of the panel made in this way. One or more openings may be provided for the outlet of cooling air near the outer perimeter of the floorboard and thus in the housing of the therapeutic lamp at its lower outer perimeter. In order to further improve the heat dissipation through the floorboard, the floorboard may preferably be provided with cooling grooves on its exterior facing outwards. This results in better heat transfer from the floor panel to the surroundings by means of radiation or convection based on the air from the surroundings that surrounds the floor panel on its outside.

To further improve the handling of the therapeutic lamp, the housing preferably has a pair of legs, spaced apart, extending substantially parallel to the first axis from the anterior region of the second tube, extending substantially by the horizontal bar. the horizontal projection extends from the bottom of the rectangular hollow portion to accommodate the ends of the horizontal masts. These rods, on the one hand, increase the stability of the entire lamp because they reinforce the housing, which is essentially fixed to the double Brewster angle, and at the same time constitute a large holding rod for holding the lamp or for attaching it to the holder.

According to another preferred further embodiment, the lamp is less heated during operation so that its color temperature lies between 3000 ° K and 3200 ° K during operation. This ensures a long lamp life.

Preferably, the electronic circuits may include a time switch for adjusting the light source illumination times and a circuit for holding up the current flowing through the light source.

The invention is further explained by way of preferred embodiments with reference to the drawing. In this drawing they show:

FIG. 1 is a cross-sectional view of a embodiment of a therapeutic lamp in side view; FIG. 2 is a front view of an embodiment of the therapeutic lamp presented in FIG. 1;

FIG. 3 is a plan view of a glass carrier carrying a mirror sandwich;

FIG. 4 is a front view of the glass support shown in FIG. 3;

FIG. 5 is a side view of a floor portion which closes the housing of the lamp at one end thereof;

FIG. 6 is a top plan view of the floor portion shown in FIG. 5;

FIG. 7 is a cross-sectional view as in FIG. 1, with a schematic representation of the main cooling air flows.

The therapeutic lamp 1 is fully presented in FIG. 1 and 2. This lamp 1 is provided with a body or a housing 2 which can be made of two plastic halves or foam plastic materials that fit together, with the two halves connected to one another in one piece. The housing 2 has a vertical tubular portion 3 and a shorter, obliquely upwardly extending tubular portion 4, wherein the central axes 31, 32 of both tubular portions 3 and 4 are enclosed with each other by a double Brewster angle, i.e., mutually bracketed by 114 ° . Both tube sections 3 and 4 are cut off by a common plane and the Brewster polarizer 5 is secured to the cross-section. The Brewster4 polarizer 5 consists of a stack of directly adjacent, consistent, elliptical tloat glass panels and is machined into a glass carrier 6, which is explained in further detail below. The stack of tloat glass panels that lie in line with one another is also called a mirror sandwich. The tube portion 4 is provided with a plate 7 of a light filter which mechanically closes and seals the tube portion 4 at its front opening for light output, leaving the inner space of the therapeutic lamp mechanically and dustproof. The panel 7 of the light filter is preferably designed as a yellow filter that transmits only light components above the wavelength of about 400 nm to 450 nm.

The vertical tube portion 3 is essentially a hollow cylinder, but has an anterior, rectangular hollow portion 8 that restricts a corresponding, rectangular interior space associated with the cylindrical inner space of the vertical tube portion 3. The rectangular hollow portion 8 extends vertically up to the front, the upper tube portion 4 and the latter are thus supported. The rectangular hollow portion 8 thus increases the overall rigidity of the therapeutic lamp 1 and its hollow interior space used to accommodate the electrical circuits 9 and the fan 10, which will be described in further detail below.

The housing has a circular support and mounting rod 11 comprising the upper half of the front tubular portion 4, forming an integral part of one tubular portion of this tubing, leaving the retaining and mounting rod 11 shown in the drawing below leaving the front tubular portion 4 below. and extending downwards in the form of two vertical legs 12 and 13, the vertical legs 12 and 13 at their lower end being interconnected by a horizontal bar 14, which is attached to a forward-projecting projection 15 of a rectangular hollow part 8. Such housing construction 2 is preferred because the lamp can take the stable position shown in FIG. 1 and in which the opening of the tubular part 4 is tilted upwards, being directly irradiated in cosmetic applications, the most common objective being irradiation, that is, the real face of the wearer, so that the person can take a comfortable sitting posture. According to a second, preferred arrangement, the therapeutic lamp may rest on the glass carrier 6, thereby pointing the second tube portion 4 obliquely upwards, thereby irradiating the desired body part, e.g. face.

Another advantage is the presence of both legs 12, 13, which are located at a distance from each other and with their help the lamp can be comfortably held or held. on which the mounting device may be firmly attached. In addition, the housing with round pole 11 is given an aesthetic design.

The components of Therapeutic Lamp 1 which are important for operation are further a metal halogen bulb 16 which is housed in a parabolic reflector 17 substantially in its focus. The parabolic reflector 17 is provided with a paraboloid-shaped reflecting surface and rests on its axial annular abutment of the vertical tube portion 3 with the free reflector edge adjacent to the intermediate, sealing powder to accommodate the sealing ring. The metal halogen lamp is electrically powered by a ring transformer 19, which is located below the reflector 17. The ring transformer 19 is in turn electrically connected to electrical circuits 9. The metal halogen lamp is designed so that the UVA and UVB parts of the light emitted are very low. .

The first annular cooling air duct 20 is made around the annular transformer between its outer circumferential surface and the inner circumferential surface of the vertical tube portion 3. At its lower ends, the first annular cooling air space 20 bounded by a floor plate 21 provided with cooling fins 25 and will be explained in more detail below. On its upper side, the first annular space 20 for cooling air is limited by a circular plate 22. The opening 23 for the cooling air outlet is made in its vertical end 3 at its lower end.

Above the circular plate 22, a second annular cooling air space 24 is made, bounded by the lower surface of the reflector 17, the inner wall surface of the vertical tube portion 3, the circular plate 22, and the rectangular hollow portion 8. The total cooling air flow caused by the fan 10, is divided into two cooling air streams, the first of which, as presented in FIG. 7, directly enters the first annular space 20 for cooling air, flows through the annular transformer 19 and the cooling fins 25 of the floor plate 21 and finally flows through the opening 23 for the cooling air outlet.

The second cooling air flow, also seen in FIG. 7, flows from the fan directly into the second annulus 24 for the cooling air located below the reflector 17, and then flows through the ducts, which are therefore provided in the vertical tube portion 3 and are not represented, to the mass carrier 6 having a mass cooling ducts 26. At the upper end of the glass carrier 6, i.e. near the tube 4, the second cooling air stream finally exits.

Particularly well in FIG. 2 can recognize a rectangular hollow part 8 that extends vertically and at its upper end supports a tubular portion 4. From the rectangular hollow part 8 extend switch and / or display elements 27 that directly affect the electrical circuits 9 or. they are powered by them. In this way, comfortable operation of the lamp can be achieved.

At its lower end, the fan 10 is shaded by a mesh 28 with a filter to prevent the risk of damage and the suction of dust particles with the fan 10.

FIG. 3 shows a glass carrier 6 carrying a mirror sandwich made of float glass plates. The glass carrier 6 is provided with a plurality of ducts 26 for flowing cooling air into which, as already described by FIG. 7, the outlet cooling air flows out of the second annulus 24 for cooling air and finally flows out at the other end of the glass carrier 6 near the second tube portion 4.

On the exterior side of the glass support 6, it can be provided with cooling slots 30, just like the floor plate 21.

In FIG. 5 and 6, the floor panel 21 is represented by its cooling fins 25. On the outside, the floor panel 21 is provided with cooling grooves 29 that facilitate heat transfer to the outside.

FIG. 6 shows a top view of the floor panel 21, showing that the cooling fins 25 are not evenly spaced, since adequate space is required for the mounting of the fasteners and / or joints. ring transformer.

Claims (8)

PATENT APPLICATIONS A polarized light biostimulation therapy lamp having: a light source essentially derived from a point source, having a power substantially between 30 W and 300 W, with a rotary parabolic reflector (17) defining a focal point and having positioned behind the light source such that the focal point substantially coincides with the point source so that the main part of the light emitted by the light source is reflected forward in a parallel beam; A Brewster polarizer (5) which is arranged in a beam of beams to produce polarized light exiting in a predetermined direction and having a cross section of at least 100 cm ² ; with a panel (7) of a light filter transmitted for components with wavelengths exceeding 400 nm to 450 nm; with an integral housing (2) preferably made of a plastic material and formed by a first tube portion (3) having a first axis (31) and a floor end perpendicular to the first axis (31) and a second tube portion (4) with the second axis (32), which with the first axis (31) encircles the angle corresponding to the double Brewster angle, i.e. 114 °, with the tubular parts (3, 4) having substantially the same and circular cross-sections and being adjacent to each other. the second is fixed and the reflector (17) with the light source is so fixed in the first tube portion (3) that there is a tight connection between them, and the first and second tube portion (4) are cut along a plane perpendicular to the plane which contains the first and second axes (32) such that the plane intersects substantially the entire cross-section of the two tube parts (3, 4) and the cross-sectional plane with the first and second axes (32) curves substantially the same angle, making the opening limited by an elliptical contour a line where the opening is closed by the polarizer (5) as well as the glass carrier (6) of thermally conductive material and by augmented o the heat-distributing rear and the panel (7) of the light filter is located in the front section of the second tube portion (4) whose inner space closes; and with a annular transformer (19) for supplying the light source in the first tube portion (3) mounted below the reflector (17), the first tube portion (3) having a rectangular hollow portion (8) extending along the front region and terminating in the second tube portion (4), wherein the electrical circuits for the light source operation are housed in the hollow space of the rectangular hollow portion (8) of the first tube portion (3), wherein the Brewster polarizer (5) consists of a mirror sandwich made of several thin, flat-paneled float glass panels which directly and coherently abut each other and are inserted into a glass support (6) provided with channels (26) for flowing cooling air while in the hollow space rectangular hollow part (8) of the first tube part (3) additionally mounted fan (10) which sucks the flow of cooling air from the surrounding air and along the reflector (17) and through the channels (26) to flow the cooling air of the Brewster polarizer (5 ) leads back to the open air. The therapeutic lamp according to claim 1, characterized in that the light source is a metal halogen lamp (16) and a first annular cooling air duct (20) is arranged around the annular transformer (19), through which a portion of the cooling air stream is directed, which it is formed by a fan (10). The therapeutic lamp according to claim 1 or 2, characterized in that a second annular channel (24) for cooling air is provided between the rear of the reflector (17) and the annular transformer (19). The therapeutic lamp according to claim 2 or 3, characterized in that the annular transformer (19) is directly thermally connected to the floor panel (21) of the therapeutic lamp, which, with its inner side, facing the interior of the lamp housing (2), provided with cooling fins (25), the opening (23) for the outlet of cooling air in the housing (2) of the lamp in the region of the outer perimeter of the floor panel (21) is made in the region of the base of the cooling fins (25). The therapeutic lamp according to claim 1, characterized in that the floor panel (21) on its outer side facing outwards is provided with cooling grooves (29). A therapeutic lamp according to any one of claims 1 to 5, characterized in that the housing (2) further has a pair of spaced legs (12, 13) extending substantially in the anterior region of the second tube portion (4) parallel to the first axis (31) and extended by a horizontal bar (14), extending from the floor of a rectangular hollow part (8) a horizontal projection (15) for receiving the ends of the horizontal bars (14) The therapeutic lamp according to claim 1, characterized in that the lamp (16) is less heated during operation such that its color temperature during operation lies between 3000 ° K and 3200 ° K. The therapeutic lamp according to one of the preceding claims, characterized in that it comprises electronic circuits, a time switch for adjusting the length of illumination of the light source, and a circuit for holding up the current flowing through the light source.