SK44396A3 - Hand-held, polarised light-radiating therapeutical lamp - Google Patents

Abstract

A polarised light-radiating therapeutical lamp (1) consists of case (2), comprising handle (21) with ventilator (4), middle part (22) and front part (23). In the case (2) there is placed a set-up (3) of light source, made of a reflector (36) arranged directly behind the lamp (42) and a polariser (33) arranged in the path of the light emitted by the lamp (42). The polariser is a Brewster polariser (33) made of a mirror sandwich of a plurality of thin, plane parallel float glass panes (34) directly superimposed and congruent, mounted in a glass frame (35). Between the set-up (3) of the light sourc and inside wall of the case (2) there is made air continous canal (26). The set-up (3) of light source has a pair of coupled cavity pipes (31, 32), which are cut with the plain, between of which normal and both axes is included Brewster angle. Reflector (36) is connected with the first pipe (31). In the handle (21) there are made slots (25) for drawing air off from the inside space. Behind the lamp (42) is side on the case (2) in the flow of cooling air placed assembling panel (38) with electric elements where electric conduction is connected.

Description

Technical field

The invention relates to polarized light,

-1For manual use, emitting a treatment lamp for biostimulation emitting polarized light. In particular, the invention relates to a therapeutic luminaire that emits polarized light of a certain intensity and wavelength while covering a certain area of area.

BACKGROUND OF THE INVENTION

DE-PS 32 20 218 describes a general biostimulating effect of polarized light. In particular, FIG. 5 of this document shows a treatment lamp using a polarizing filter. The luminaire is suitable for creating a light beam with a diameter of 55 mm, and the lamp power is 150 W. The lamp produces a lot of heat and is cooled by a fan. Much of the power is lost in the form of heat and the efficiency is relatively small, which also causes serious cooling problems. Furthermore, the use of this luminaire is not optimal when performing both optimal cooling and optimum efficiency.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a treatment lamp of a kind in which, on the one hand, a structure is provided which is easy to handle and, on the other hand, an optimum function can be achieved with regard to cooling.

SUMMARY OF THE INVENTION

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

-2 individually, the use of a Brewster polarizer with a mirror sandwich and directly stacked float glass discs achieves high polarization efficiency, while on the other hand, the easy cooling of the float glass mirror sandwich is realized because, for example, there are no insulating air slots between the individual discs glass.

Furthermore, the immediate application of the float glass discs to each other prevents the polarizer from getting dirty by ingress of dust particles between the float glass discs. This results in a longer lamp life.

According to a preferred further embodiment of the invention, the light filter plate closes the second hollow cylinder. Thereby, the second hollow cylinder with respect to light transmission is closed, but at the same time mechanically sealed against the ingress of dust. Correspondingly, the reflector closes the first hollow cylinder by means of a seal, thereby sealing the entire tubular device hermetically sealed from the first and second hollow cylinders and thus remaining protected from soiling.

According to another preferred further embodiment, the light source arrangement in the central and front parts is arranged such that the space around the light source arrangement is larger near the polarizer than near the reflector. This results in optimal cooling air flow.

According to a preferred embodiment, the first angle is between 105 and 120 degrees.

According to a further preferred embodiment, the handle is provided with finger bulges on its outer face, on the side facing away from the light exit opening, with a front portion. In this way, the treatment lamp can be optimally held and directed to the treatment site, for example the person's kidney.

Preferably, slits are provided at the lower end of the handle.

This means that the outgoing cooling air flow is no barrier.

According to a further preferred embodiment of the invention, the float glass discs have elliptical shapes and the girder are in the form of an elliptical receiving pan with an elliptical bottom and a wall extending around a substantial part of the bottom, the wall being provided with a plurality of locking projections. Furthermore, the mirror sandwich may lie directly on the cutting surface of the tubular device, thereby ensuring further holding.

Preferably, the filament lamp is a metal halogen lamp assembled with a reflector that is at least 5% bright during operation. This results in a longer service life. The filament lamp is particularly preferably designed to emit either no or only a small amount of ultraviolet light.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below with reference to the preferred embodiments thereof, which are described with reference to the accompanying drawings, in which: FIG. 1 shows a longitudinal sectional view of an embodiment of a medical light according to the invention; FIG. 2 is a side view of the treatment lamp of FIG. 1, FIG. 3 is a front view of the treatment lamp of FIG. 1, FIG. 4 is a front view of the treatment lamp obliquely from below, FIG. 5 is a perspective view of a treatment light source; FIG. 6 shows an enlarged detail of a section of Brewster polarizer; FIG. 7 is a plan view of the glass beam, FIG. 8 shows a side view of the glass beam, FIG. 9 shows section A-A of FIG. 7, and FIG. 10 is an enlarged representation of the individuality indicated in FIG. 9 as detail 1.

EXAMPLES OF THE INVENTION

The treatment lamp 1 shown in FIG. 1 consists of three components, i.e. a housing 2. a light source and fan arrangement 2. The housing 2 itself consists of a handle 21, a domed central portion 22 and a front portion 22, the shape of which is clearly visible in FIG. 1 to FIG. 4. The housing 2 is preferably made of two plastic parts adapted to each other, which form a hollow space for accommodating the other components.

The light source arrangement 2 is in the middle part 22 and the front part 23 of the housing 2 in the position shown in FIG. 1 is arranged centrally such that a gap is formed substantially everywhere between the inner wall of the housing and the light source arrangement. The term centrally means that this gap in the direction perpendicular to the drawing of FIG. 1 is the same on both sides. As shown in FIG. 1, the light source arrangement 2 is not perfectly centered in the drawing.

The light source arrangement 2 is comprised of two blunt-welded cylindrical tubes 21, 32, whose axes are at an angle of about 114 degrees to each other, corresponding to a double Brewster angle. Both tubes 21, 22 are cut at the outer top according to the plane in which the intersection of the axis of the tubes lies and the elliptical opening thus formed is covered by the Brewster polarizer 22. The light source arrangement 2 is evident from the perspective view of FIG. 5th

Fig. 6 shows a section of a Brewster polarizer 22 in section. The Brewster polarizer 33 is comprised of a plurality of, for example, 5 consecutively arranged, thin, planar parallel, elliptical float glass discs 34, which lie immediately, i.e. without forming gaps, on top of each other. the float glass discs 34 are embedded in the glass beam 35 shown in FIG. 6 shown only clean

The float glass discs 34 reach high on the other side of the mirror sandwich because these lie schematically.

the polarization efficiency, while the easy cooling of the float glass discs is realized directly on top of each other and are not separated from each other by insulating air slots between the glass discs. The float glass discs are therefore in good contact with each other to conduct heat, so that the mirror sandwich can be regarded as a one-piece component due to its good heat conducting properties. Furthermore, by immediately placing the float glass discs on top of one another, it is achieved that dust particles cannot get between the glass discs. This gives Brewster's polarizer a high efficiency and a long service life.

A detailed illustration of the glass girder in which the mirror sandwich is fitted can be seen from FIG. 7 to FIG. 10. The glass beam 35 is in the form of an elliptical receiving pan with an elliptical bottom 39, and around a substantial portion of the bottom 22 extending through the stitch 12 of the wall 40 is provided with a plurality of locking projections 41 which laterally engage the mirror sandwich. 7 to FIG. 10 not shown. The wall 40 does not have to extend around the entire elliptical bottom 22, so that, for example, a mirror sandwich can be mounted together with the girder 35 tightly on the tubes 21, 22 without the girder 35 striking the housing 2. The float glass discs therefore lie directly on the surface. the cutting edges of the tubular arrangement of tubes 21 and 22, which are cut at Brewster angle. In this case, the float glass discs 21 or the glass beam 35 are sealed by means of a seal to the cutting surface, as well as the reflector 36 and the light filter plate 37 to the tubes 31 and 22, as explained below. Thereby, the inner space of the tubular device formed by the tubes 21 and 22 is mechanically sealed so that no dust can enter the inner space. A bulb 12, in particular a metal halogen, is arranged at the rear end of the tube 21

The light bulb with a reflector 36 which is held pressed tightly on the circular axial inner leg of the tube 31, wherein a seal (not shown) is arranged between the circular, axial inner leg and the reflector 36 in particular.

Incandescent lamp 42 emits visible and infrared light axially forward, with an incidence angle of 57 degrees on the Brewster polarizer 33. The bulb 42 is designed so that it does not emit as well ultraviolet light, which must be prevented due to the risk of fire to the occupant and to unwanted spot browning. The lamp power is approximately 20 W, but in no case should it be greater than 8 W to 100 W, since the cooling conditions are basically optimal only below this threshold power.

The float glass discs of the Brewster polarizer 33 reflect light parallel to the axis of the tube 22, the reflected light being linearly polarized. The unreflected light components impinge on the black inner surface of the enclosing plate 35 and the heat generated is dissipated by the cooling air.

The interior of the light source arrangement 2 is closed at the front end of the tube 32 by a yellow light filter plate 22. The purpose of the light filter plate 37 is to filter the spectral components below about 400 to 450 nm of light rays reflected on the polarizer 33 and, as already pointed out, to mechanically close the interior of the light source arrangement 2 so as not to damage the optical properties of the elements arranged there. .

The side in the cooling air flow is under the bulb £ 2. The electrical connection line extends up to the mounting plate 22, on which the fuse is also arranged, as well as a plurality of electrical components. It is useful if it is in series

An electrical attenuator is provided with the bulb 42 so that the bulb 42 is about 2 to 5% under-heated. Ignition of the bulb 42 increases both its lifetime and shifts the spectral distribution of the light emitted towards the infrared region (by reducing the effective light temperature), thereby increasing the penetration depth of the rays. It is also possible that such spectral distribution is more favorable to biostimulation. Lowering the light temperature also reduces power consumption. Ignition of the bulb 42 can also be achieved by reducing the supply voltage. If the rated lamp voltage is, for example, 12 V, the transformer supplying the lamp can be sized to supply approximately 11 to 11.4 V.

The fan 1 is directed in the axial direction in the handle 21 axially opposite to the bulb 42 and draws air into the interior of the housing through the inlets 24. Fig. 3 formed around the light source arrangement 2 in the housing. The drainage takes place through the slits 25. see FIG. Fig. 1 and FIG. 4, at the free end of the handle 21. Cooling air flows in the interior of the housing along the entire surface of the housing of the light source arrangement 2. In FIG. 1, this flow is represented by arrows.

The shape of the housing shown in the drawings is not aesthetically pleasing, but also leads to very favorable cooling. Downstream of the closure plate 22 and in the region of the upper end of the tubes 21, the volume of the interior space of the enclosure due to the vaulting of the middle portion 22 of the enclosure is greatest, and the flow rate is sufficient to dissipate heat from the large surface of the enclosing plate 33; consequently, the inner space in the region of the bulb decreases, thereby increasing the air velocity substantially. In this duct 26 air flows rapidly through the parabolic surface of the reflector 36 with the bulb 12, thereby providing intense cooling, and the operating temperature does not exceed the permissible values. The bulb temperature of the bulb 42 is not greater than about 20, even after prolonged operation of the bulb

-8 degrees above ambient temperature.

The axis of the handle 21 stands slightly at an angle to the bulb axis, i.e. the direction of the light rays emerging from the treatment lamp 1 extends at an angle between 105 and 120 degrees, in particular 105 to 110 degrees to the axis of the handle. This direction allows a very comfortable hold and comfortable light treatment.

In the case of a 20 W metal halogen lamp with a 50 mm reflector diameter, the inner diameter of the tubes

31. 32 also selected about 50 mm. This therapeutic light emits parallel, polarized light in a circular beam of 50 mm diameter and the light power density is approximately 50 mW / cm ² .

Claims (7)

PATENT CLAIMS Medical lantern emitting polarized light, with a housing (2), a handle (21) integral with the housing (2), a filament lamp (42) having an electrical power of not more than 100 W, placed in the housing (2), a reflector (36) after the bulb (42), a polarizer (33) arranged in the light beam of the light emitted by the bulb (42), a light filter plate (37) to filter out the ultraviolet spectral components of the light emitted, 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 of a plurality of thin, planar parallel float disks which are immediately and coincidently stacked on one another and set in a glass support (35), a casing (2) has three consecutive and directly connected parts which define a common interior space, the first part being essentially tubular an axle (21), a second part an arched central part (22) connected at one end thereof to an end of the handle (21), and a third part a cylindrical front part (23) connected to the other end of the middle part that the front part (23) has an axis that grips with the axis of the handle (21) a first obtuse angle that the light source arrangement (3) with an enclosed interior space within the housing (2) is arranged with a gap relative to the inner walls of the same that around this light source arrangement (3). an air passageway (26) is formed such that the light source arrangement has a pair of hollow cylinders (31, 32) connected to each other with axes that enclose a hollow obtuse angle that is twice as large as The -10Brewster angle that the hollow cylinders are cut by a surface between which the normal and the two axes is now clamped Brewster angle that the bulb (42) and the reflector (36) are connected to the first hollow cylinder (31) that the Brewster polarizer (33) is located within the light source arrangement (3) and deflecting a portion of the light coming out of the bulb (42) towards the second hollow cylinder (32), and that a fan (4) is arranged inside the handle (21) to allow the channel (26) ) formed around the entire surface of the housing of the light source arrangement to suck in fresh air, the handle (21) being provided with slots (25) for exhausting air from the interior. The medical light according to claim 1, characterized in that the light filter plate (37) closes the second hollow cylinder (32). The medical light according to claim 1, characterized in that the light source arrangement (3) is arranged in the center and front (22, 23) such that the space around the light source arrangement is larger near the polarizer (33) and near the reflector. (36) narrower. A medical lantern according to characterized by between 105 and 120 degrees. of claim 1, wherein the first angle lies The medical lantern according to claim 1, characterized in that the handle has bulges on its outer surface to locate the fingers on its side facing away from the light exit opening of the front (23). -116. The medical lantern according to claim 5, characterized in that slits (25) are provided at the lower end of the handle (21). The medical lantern according to claim 1, characterized in that the float glass discs (34) have elliptical shapes and the glass beam (35) has the shape of an elliptical receiving pan with an elliptical bottom and a wall extending around a substantial part of said bottom. a plurality of locking lugs that engage and hold the mirror sandwich. The medical light according to claim 2, characterized in that the bulb (42) is a metal halogen bulb assembled with a reflector (36), and is in operation at least 5% illuminated.