SK281804B6 - Therapeutical lamp - Google Patents

Abstract

The therapeutic light consists of a housing (2) which is formed by a first tube (3) and a second tube (4) in which a light source is located in the focus of the reflector (17), under which the transformer (19) is located. A light filter plate (7) is mounted at the upper end of the second tube (4). The first central axis (31) of the first tube (3) bends with the second central axis (32) of the second tube (4) an obtuse angle of about 114 ° corresponding to the double Brewster angle. The tubes (3, 4) are truncated according to the cutting plane, thereby forming a bore of the Brewster polarizer (5), which consists of a float glass mirror sandwich which is immediately and coincident and fixed in a beam (6) in which channels (26) are formed. A rectangular hollow part (8) with a rectangular interior space is connected to the front area of the first tube (3), in which electric switching circuits (9) are provided for operating the light source consisting of a halogen lamp (16) with metal vapor and a fan (10) for guiding cooling air around the reflector surface (18) and through the channels (26) into the free space

Description

Technical field

The invention relates to a therapeutic luminaire for biostimulation with polarized light, which emits polarized light of a certain intensity and wavelength, while covering a certain area.

BACKGROUND OF THE INVENTION

DE 32 20 218 describes a known general biostimulating effect of polarized light. In FIG. 5 of this patent is shown a therapeutic lamp in which a polarizing filter is used. The therapeutic luminaire is suitable for creating a light beam with a diameter of about 55 mm and a lamp power of 150 W. The lamp produces a lot of heat and is cooled by a fan. In frequent use, it makes sense to irradiate an average surface area greater than 100-300 cm ³ , which would, for example, have the lamp power to be up to six times greater, causing serious cooling and handling problems due to the very heavy wiring for the power required.

SUMMARY OF THE INVENTION

The above-mentioned drawbacks are largely eliminated by a polarized light biostimulation therapeutic luminaire consisting of an integral housing, mainly a plastic material consisting of a first tube and a second tube, with a 30 W to 300 W light source formed as a spot a source which is located in the focus of the rotating parabolic reflector for reflecting a major portion of the light forward, which, together with the light source, is fixed in the first tube such that a sealed connection is formed therebetween; components of wavelengths of more than 400 nm to 450 nm, the first central axis of the first tube having an obtuse angle of about 114 ° corresponding to the double Brewster angle with the second central axis of the second tube, the tubes having the same circular cross-sections and cut along the cutting plane the same angle with a first and a second centerline and extending vertically to the plane containing the center axes to form an aperture bounded by an elliptical contour line, the brewery polarizer aperture having a cross-section of at least 100 cm ² closed by a thermal conductive material and enlarged backside a heat distribution device, wherein a toroidal transformer is placed under the reflector in the first tube for supplying the light source, and a rectangular hollow portion adjoins the front region of the first tube, ending on the second tube, with electrical switching circuits disposed in the rectangular hollow space the light source and the Brewster polarizer consists of a mirror sandwich of planar parallel discs of glass, the essence of which is that the Brewster polarizer consists of float glass discs which are immediately and consistently stacked and which are is provided in a beam in which the channels for the flow of cooling air into the free space are formed, wherein in the rectangular interior of the rectangular hollow part of the housing is located in the area of the light source and toroidal transformer connected to the electric switching circuits; to guide the cooling air around the reflector surface and through the channels to the free space.

According to a preferred embodiment, the light source is a halogen metal vapor lamp. A first circular channel is provided around the toroidal transformer to direct a portion of the cooling air away from the fan.

According to a further preferred embodiment, a second circular cooling air channel is formed between the reflector surface and the toroidal transformer.

According to a further preferred embodiment, the toroidal transformer is thermally conductive connected directly to a bottom plate which is fixed at the lower end of the first tube and which is provided with cooling fins on its inner side facing the inside of the housing. A cooling air outlet opening is provided in the housing in the region of the outer periphery of the bottom plate at the base of the cooling fins.

According to a further preferred embodiment, the bottom plate is provided on its outside facing the free space with second cooling grooves.

According to a further preferred embodiment, the housing is provided with a pair of spaced apart legs extending from the front region of the second tube parallel to the first central axis and connected at their lower end by a horizontal bar. A horizontal projection is formed at the lower end of the rectangular hollow portion for attaching the ends of the horizontal bar.

According to another preferred embodiment, the lamp is connected in series with the attenuator to heat the lamp below 100% and to produce a color temperature of 3000 to 3200 ° K.

According to a further preferred embodiment, the electrical switching circuits are provided with a timer for adjusting the length of the lamp illumination periods and a circuit for delaying the current flowing through the lamp.

The main advantage of the therapeutic luminaire according to the invention is its simple construction allowing manipulation with the therapeutic luminaire. Another advantage of the therapeutic luminaire is to achieve its optimal function, for example with respect to the easy cooling of the mirror sandwich. By sealing the interior space and placing the discs directly on top of each other, a longer service life of the therapeutic lamp is also achieved, with which a high polarization efficiency is achieved. The use of horizontal rods increases the stability of the entire therapeutic lamp, while the horizontal rods are simultaneously large handles suitable for handling or attaching the therapeutic lamp.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a longitudinal section through a therapeutic lamp; FIG. 2 is a front view of the therapeutic lamp; FIG. 3 shows a plan view of a beam, FIG. 4 shows a cross-section of a beam, FIG. 5 shows a cross-section of the bottom plate, FIG. 6 shows a plan view of the bottom plate and FIG. 7 is a longitudinal section of the therapeutic light of FIG. 1 with the main cooling air streams.

DETAILED DESCRIPTION OF THE INVENTION

The therapeutic luminaire 1 for polarized light biostimulation with a certain intensity and wavelength, shown in FIG. 1 and 2, consists of an integral housing 2, in particular of a plastic material which is formed by a vertical tube

The casing 2 is made of two mutually matching halves of plastic or foamed plastic material, the two tubes 3, 4 being formed in one piece.

The first central axis 31 of the first tube 3 forms an obtuse angle of about 114 ° with the second central axis 32 of the second tube 4, which corresponds to a double Brewster angle. Both tubes 3, 4 have the same circular cross-sections and are cut at the intersection of the central axes 31, 32 according to a cutting plane that is at the same angle with the central axes 31, 32 and extending vertically to the plane containing the central axes 31, 32. , bounded by an elliptical contour line having a cross - section of at least 100 cm ² . Located on the cutting plane is a Brewster polarizer 5, which consists of a mirror sandwich disposed in a beam 6. The mirror sandwich is formed by a plurality of arranged parallel parallel elliptical float glass discs which are adjacent to each other, i. without gaps between them. A plurality of channels 26 for cooling air flow are formed in the beam 6. First cooling grooves 30 are formed on the outside of the beam 6.

The first tube 3 consists essentially of a hollow cylinder with a cylindrical inner space followed by a rectangular inner space formed in the rectangular hollow part 8, adjoining the first tube 3 in the front part and extending vertically upwards to the front of the second tube 4, In the upper part of the rectangular interior of the hollow part 8 there are electrical switching circuits 9 and in its lower part there is a fan 10 with a suction side exposed to the ambient air, which is equipped with a grille 28 s at its lower end. A filter 27 is provided on the outside of the rectangular hollow part 8 for preventing injury and entrainment of the dust particles by means of a fan 10. The control elements 27 are formed by switching and / or indicating elements which act directly on the electrical switching circuits 9 Janey. The electrical switching circuits 9 are provided with a timer for adjusting the length of the illumination period of the lamp 16 and a circuit for delaying the current flowing through the lamp 16.

In the vertical first tube 3, a rotating parabolic reflector 17 with a paraboloid reflector surface 18 is dust-tightly mounted by means of a sealing ring, in which a light source consisting of a halogen vapor lamp 16 with a metal vapor of 30 W to 300 W is located. that the proportion of the UVA and UVB components of the emitted light is as low as possible. The lamp 16 is connected in series with the attenuator to heat the lamp 16 below 100% and to produce a color temperature between 3000 and 3200 ° K. A toroidal transformer 19 is provided below the reflector 17 for supplying the therapeutic lamp 1 with an electric current, which is electrically connected to the switching circuits 9. At the lower end of the first tube 3, a lower plate 21 is mounted perpendicular to the first central axis 31. the housing 2 is equipped with cooling fins 25 supported by the toroidal transformer 19, and a circular disk 22 is placed between it and the reflector 17. The toroidal transformer 19 is therefore thermally conductive connected directly to the bottom plate 21. The cooling fins 25 are not evenly formed since the corresponding mounting space for the fastening elements or the toroidal transformer 19 is required. The bottom plate 21 is provided on its outside facing the free space with second cooling grooves 29 to facilitate the transfer of heat outwards. Around the toroidal transformer 19, a first circular duct 20 for cooling air is formed between its outer peripheral surface, the inner peripheral wall of the first tube 3, the circular disk 22, and the bottom plate 21. At the lower end of the first tube 3, at least one aperture 23 is provided in the region of the outer periphery of the bottom plate 21 and at the base of the cooling fins 23 to exit the cooling air from the first annular channel 20. Between the circular disk 22, reflector 17, 8, a hollow circular duct 24 for cooling air is provided.

In the upper end of the second tube 4, a light filter plate 7 is fixed by means of a seal, which thus mechanically and tightly closes the front opening of the second tube 4 for the light output. The sealing of the light filter plate 7 and the reflector 17 by means of a seal creates an interior space inside the therapeutic light 1, which is mechanically and dust tightly closed. The light filter plate 7 is designed mainly as a yellow filter that only transmits light components over a wavelength of about 400 to 450 nm.

The housing 2 has a spherical support and mounting rod 11 which surrounds the upper half of the second tube 4. The mounting rod 11 is formed in one piece with the second tube 4. In addition, the mounting rod 11 gives the housing 2 an aesthetically pleasing shape. The mounting rod 11 exits the second tube 4 and extends downwardly in the form of the first vertical leg 12 and the second vertical leg 13. The vertical legs 12, 13 at their lower end are connected to the horizontal rod 14 and are fixed to the projection 15 of the rectangular hollow portion 8, which is oriented forward. Such a housing design 2 is advantageous because the therapeutic lamp 1 can assume a stable, in FIG. 1 shows the position in which the opening of the second tube 4 is inclined slightly upwards. For cosmetic use, the most common goal is to illuminate the face of a treated person, which can be directly lit so that the person can provide a comfortable sitting position. According to another preferred position, the therapeutic light 1 can lie on the beam 6, with the second tube facing upwards and thus illuminating the desired part of the body, for example the face. Since the vertical legs 13, 14 are spaced apart, the therapeutic lamp 1 can be conveniently held or a positioning device can be mounted on the vertical legs 13, 14.

The total cooling air flow generated by the fan 10 is divided into two cooling air streams, the first of which, as shown in FIG. 7, penetrates directly into the first annular channel 20, blows the toroidal transformer 19 and the cooling fins 25 of the bottom plate 21, and finally flows through the opening 23 to exit the cooling air into the free space.

A second cooling air flow, also seen in FIG. 7, flows from the fan 10 directly to the second annular channel 24 around the reflector 17 and then passes through channels (not shown) formed in the vertical first tube 3 to a beam 6 having a plurality of cooling air flow channels. Finally, at the upper end of the beam 6, i.e. near the second tube 4, a second flow of cooling air flows into the free space.

Claims (8)

PATENT CLAIMS Therapeutic lamp (1) for polarized light biostimulation, consisting of an integral housing (2), in particular a plastics material consisting of a first tube (3) and a second tube (4), wherein a light housing is provided in the housing (2) a source of 30 W to 300 W, designed as a point source, which is located in the focus of a rotating parabolic reflector (17) for reflecting a major proportion of the light forward, which, together with the light source, is fixed in the first tube (3) a sealed connection is formed at the upper end of the second tube (4) and the light filter plate (7) is transparent to components of wavelengths of more than 400 nm to 450 nm, the first central axis (31) of the first tube (3) being an obtuse angle of about 114 ° corresponding to the double Brewster angle by the central axis (32) of the second tube (4), the tubes (3, 4) having the same circular cross-sections and being cut along the cutting plane and the same angle with the first and second center axes (31, 32) and extending vertically to the plane containing the center axes (31, 32) to form an aperture bounded by an elliptical contour line, the aperture of the Brewster polarizer (5) with the beam (6). having a cross-section of at least 100 cm ² is enclosed by a thermal conductive material and an enlarged heat-distributing backside, wherein a toroidal transformer (19) is placed under the reflector (17) under the reflector (17) and on the front area of the first the tubes (3) are connected by a rectangular hollow part (8), which ends up on the second tube (4), and in the rectangular interior of the rectangular hollow part (8) there are electric switching circuits (9) for operating the light source and Brewster polarizer (5) ) consists of a mirror sandwich of planar parallel disks of glass, characterized in that the Brewster polarizer (5) consists of float disks glass, which are immediately and consistently lying on top of each other and which are fixed in a beam (6), in which channels (26) are formed for flowing cooling air into the free space, wherein in the rectangular interior of the rectangular hollow part (8) of the casing (2) ) in the region of the light source and the toroidal transformer (19) connected to the electrical switching circuits (9), there is a fan (10) with a suction side exposed to the ambient air and for guiding cooling air around the reflector surface (18) and through channels (26) into free space. Therapeutic lamp according to claim 1, characterized in that the light source is formed by a metal vapor halogen lamp (16), wherein a first annular channel (20) is formed around the toroidal transformer (19) for guiding a portion of the cooling air from the fan (16). 10). Therapeutic lamp according to either of Claims 1 and 2, characterized in that a second cooling air ring (24) is formed between the reflector surface (18) and the toroidal transformer (19). Therapeutic lamp according to one of Claims 1 to 3, characterized in that the toroidal transformer (19) is a thermal conductor connected directly to the bottom plate (21) which is fixed at the lower end of the first tube (3) and which is an inner side facing the inside of the housing (2) provided with cooling fins (25), wherein a cooling air outlet (23) is provided in the housing (2) in the region of the outer periphery of the bottom plate (21) at the base of the cooling fins (25). Therapeutic lamp according to claim 4, characterized in that the bottom plate (21) is provided with second cooling grooves (29) on its outside facing the free space. Therapeutic lamp according to one of claims 1 and 4, characterized in that the housing (2) is provided with a pair of vertical legs (12, 13) spaced apart from one another, extending parallel to the front region of the second tube (4). with a first central axis (31) and are connected at their lower end to each other by a horizontal bar (14), and at the lower end of the rectangular hollow part (8) a horizontal projection (15) is formed for attaching the ends of the horizontal bar (14). Therapeutic lamp according to claim 2, characterized in that the lamp (16) is connected in series with the attenuator to heat the lamp (16) below 100% and to produce a color temperature of 3000 to 3200 ° K. Therapeutic lamp according to claim 1, characterized in that the electrical switching circuits (9) are provided with a timer for adjusting the length of the lamp illumination periods (16) and the delayed increase of the current flowing through the lamp (16).