WO2019212381A1 - Led lamp having cylindrical optical waveguide - Google Patents

Abstract

A solution relates to lighting technology, specifically to lighting devices based on an optical waveguide having an end backlight of LEDs, which can be used for inside and outside illumination. The technical effect is to improve heat removal, increase luminosity and expand the range of LED lamps. The invention comprises a hollow housing (2), a base (9), a hollow cylindrical optical waveguide (3) having applied elements of optical heterogeneity, a cylindrical heat sink (1) made of aluminium, which is arranged in a cavity of the optical waveguide (3) and fastened in the cavity of the housing (2) so as to be capable of heat exchange. The LEDs are mounted on a plate (4) so as to be capable of illuminating an end surface of the optical waveguide (3). The plate is designed in the form of a ring and is arranged on a circular projection (5) of the cylindrical heat sink (1). A fixing cover (6) has through openings (11), and there are through openings (8) in the housing (2), which along with the cavity of the heat sink (1) and optical waveguide (3) create an air convection channel.

Description

 LED lamp with a cylindrical light guide

Technical field

 The technical solution relates to lighting engineering, namely, lighting devices based on a fiber with end-illuminated LEDs, which can be used for indoor and outdoor lighting.

Known level

 When lighting on the streets and open areas, it is necessary to carry out lighting so that the light does not propagate upward (this is unacceptable in many countries). At the same time, since the lamps emit light in all directions, it is necessary to arrange a reflector on top of the illuminator, which returns part of the light directed upward to illuminate the ground under the lamp. Part of the light is lost and the efficiency of the illuminator decreases. In addition, especially when using an LED illuminator with a small emitting surface, direct light has a blinding effect. Also, with an increase in the power of base lamps, cooling of LEDs causes difficulty, since the radiator cooling LEDs do not have sufficient area, or the lamp turns out to be very large.

The EdgeLighting effect is known when the LEDs emit at the end of a transparent sheet fiber made of glass, polycarbonate, acrylate or other optically transparent materials. The light is distributed along the fiber, repeatedly reflected from its walls and going outside if the angle of incidence of light on the surface is more than critical. If points of optical inhomogeneity are applied to the surface of the fiber, then falling on them, the light is scattered, and part of the radiation goes outside through the surface of the fiber.

Known LED lamps containing a housing-radiator; means for connecting to the electric network, in the form of an Edison cap fixed to the lamp housing; a light guide structure (light guide), the light emitting surface of which is formed by rotation of a second-order curve provided with an end surface; an annular board with LEDs, installed with the possibility of LEDs illuminating the end surface of the fiber, while the light emission of the LEDs is directed longitudinally to the axis of the lamp, and through ventilation ducts (EP 2796784, IPC F21V29 / 00, published on 10.29.2014).

Another well-known analogue is a lighting device containing a housing with means for connecting to an electric network, a light guide having an end surface and a surface equipped with optical heterogeneity elements, a printed circuit board mounted on a radiator and made in the form of a ring on which LEDs are mounted with the possibility of irradiating the end surface of the light guide ( EP 3190336, IPC F21V 8/00, 07/12/2017).

The closest is an analogue containing the largest number of matching features and disclosed in US2011 / 0309735, IPC H01J7 / 24, published on December 22, 2011, having a radiator case with through ventilation holes; means for connecting to the electric network in the form of an Edison cap fixed to the lamp housing; a hollow cylindrical waveguide having two end surfaces and provided with optical heterogeneity elements on the side surface; a board in the form of a ring with LEDs installed with the possibility of lighting one or both of the end surfaces of the fiber; a fiber optic cover that has through ventilation holes.

 These analogs create scattered light radiation in a solid angle of up to 270 steradians and do not imply the creation of a high power lamp, because have an insufficient heat exchange surface for cooling the LEDs.

Known LED lamp comprising a housing, a light diffuser in the form of a hemisphere, a hollow cylindrical heat sink mounted in the housing and provided with an annular protrusion on the side surface, an annular LED board mounted on a protrusion of a cylindrical heat sink with the possibility of radiation into the hemisphere of the light diffuser (EP2792944, IPC F21V 29/00, published September 13, 2017). The disadvantage of this analogue is the limited distribution due to the location of the light sources and the shape of the diffuser.

The technical result is the improvement of heat dissipation, allowing the use of powerful LEDs, increase light power and expand the arsenal of LED lamps with a large light-emitting surface.

Short description

 The technical solution is characterized by the following set of features:

 LED lamp with a cylindrical waveguide, containing:

 a hollow body of heat-conducting material having; a remote part for securing means for connecting to the power grid;

 a hollow cylindrical fiber having a lateral light-emitting surface, provided with optical heterogeneity elements and end surfaces at the ends of the fiber, one of which is placed in the cavity of the housing;

 a printed circuit board in the form of a ring with LEDs mounted to illuminate the end surface of the fiber;

 a fixing cover fixed to the second end of the cylindrical fiber;

ventilation duct including cavity

optical fiber and through holes in the housing and in

fixing cover;

 means for connecting to the mains,

mounted on a remote part of the housing;

a hollow cylindrical heat sink, the surface of which is divided into two parts by an annular protrusion, on which an annular board is mounted with the possibility of illuminating the end surface of the fiber, the first part the heat sink is fixed in the housing, and the second part of the heat sink is placed in the cavity of the light guide so that between the heat sink and the light guide is formed

ventilation gap forming with elements

ventilation channel single convection

space, and the fixing cover is connected to

cylindrical heat sink with elastic clamps,

 In the cavity of a cylindrical heat sink for

installation of the LED power supply, an electrically isolated compartment is made, the wall of which forms a cavity with the wall of a cylindrical

heat sink;

 The hollow cylindrical heat sink is made of aluminum or another material having good thermal conductivity, which allows you to effectively remove heat from the LEDs.

 To increase the efficiency of heat transfer, holes can be made in the wall of the cylindrical heat sink, for example, in the form of longitudinal cutouts, which, together with other elements forming the ventilation channel, ensure the creation of a stable convection flow. In addition, the presence of cutouts makes it easy to lay conductors to connect the power source to the LED board.

 Circular protrusions on a cylindrical heat sink can be formed by plastic deformation of the heat sink wall.

Another option for creating a circular protrusion may be the implementation of a cylindrical heat sink from tubes of different diameters inserted one into another. In this case, the width of the protrusion will be equal to the wall thickness of the tube of larger diameter.

 Equivalent to the previous one is the embodiment of a circular protrusion in the form of a heat-conducting ring, which is placed on the outer surface of the cylindrical heat sink, and the width of the step is selected taking into account the width of the ring board.

 An annular limiter is installed between the end surface of the fiber and the LED board, the function of which is to provide the smallest possible distance between the end of the fiber and the LED housing, press the LED board against the protrusion surface on the cylindrical heat sink to improve heat transfer between them and center the fiber relative to the housing and the cylindrical heat sink. To perform these functions, the annular limiter has an external protrusion located between the surface of the LED board and the end surface of the fiber, which prevents mechanical contact of the fiber with the LEDs and ensures the board is pressed against the surface of the protrusion on the heat sink. The clamping force of the board to the protrusion on the heat sink is created by fixing the fixing cover, due to the presence of an elastic ring gasket between the fixing cover, on the one hand, and the ends of the fiber and the heat sink, on the other hand.

In an embodiment of the claimed device with a heat sink having a part fixed in the housing with one annular protrusion on the opposite side the heat sink is fixed with a fixing cover having through ventilation holes that are part of the ventilation duct.

 Elements of optical inhomogeneity can be located both on the surface of a cylindrical fiber and in the body of the fiber. Moreover, the latter option has the advantage that it is not prone to contamination during operation of the lamp.

 In another embodiment, to create high-power LED lamps, the fiber has an extended surface, and the lamp is equipped with two housings, each of which has a cylindrical heat sink fixed in the cavity of the fiber, as described above for the case with one housing. In this case, the ventilation channel includes holes in the housings, the cavity of the heat sinks and the cavity of the light guide. At the same time, an annular board with LEDs installed with the possibility of lighting the corresponding ends of the surface of the fiber is installed on the annular protrusions of each heat sink.

 As a means of connecting to the mains for lamps with one housing, a screw cap or caps of a different design can be used, which allows connecting to the mains. For lamps with two cases, the screw base is inconvenient to use.

White, red, and other types of LEDs can be installed on printed circuit boards, providing a different spectrum of light emission. Graphic materials

 The technical solution is illustrated by the following graphic materials:

 Figure 1 - the appearance of the LED lamp,

 figure 2-axial section of a variant of the LED lamp, with a protrusion on a cylindrical heat sink formed by the method of plastic deformation of the wall of the heat sink,

 Fig. 3 is an enlarged image of a fragment C of the axial section indicated in Fig. 2,

 figure 4 is a three-dimensional image of a variant of the LED lamp shown in figure 2, in a parsing,

 5 is an external view of a double-ended LED lamp,

 6 is a cross section of a double-ended LED lamp shown in Fig. 5

 In the drawings, the elements of the LED lamp are shown by the following symbols:

 1- cylindrical heat sink,

 1.1, 1.2 - the first and second parts of a cylindrical heat sink,

 2 - heat conductive housing,

 2.1, 2.2, 2.3 - the first, second and third part of a heat-conducting housing,

 3 - a hollow cylindrical fiber,

 3.1, 3.2 - the first and second end of the cylindrical fiber,

 4 - ring-shaped board with LEDs,

 5 - an annular protrusion on a cylindrical heat sink,

6 - a fixing cover, 8 - ventilation hole in the housing,

 9 - means for connecting to the power grid (base)

10- longitudinal cut on a cylindrical heat sink,

11- ventilation hole in the fixing cover,

12- power supply compartment,

 13 - ventilation cavity between the light guide and the cylindrical heat sink,

 14 - ventilation cavity in a cylindrical heat sink,

 15 - ventilation cavity between the power supply compartment and the housing wall,

 16-ring limiter,

 17- collet rivet for attaching the heat sink to the body,

 18 - end surface of the fiber,

 19- reflector

 20- wall of the compartment for the power source,

 21- elastic ring gasket.

The LED base lamp contains a hollow plastic housing 2, a means for connecting to the electric network, for example, a socle 9, a light guide 3 made in the form of a hollow cylinder, the first and second ends of which have an end surface, fixed on it. In this case, the fiber is equipped with elements of optical heterogeneity (not shown in the drawing), which ensure the scattering of radiation and its exit beyond the fiber. It should be noted that the elements of optical heterogeneity can be formed on the cylindrical surface of the fiber from the outside or inside. To increase the efficiency of using the light flux, the inner surface of the fiber can be equipped with a reflector 19 made in the form of a cylindrical insert or film, the surface of which has reflective properties.

 In the version of the lamp with one cap, hollow

cylindrical heat sink 1 is made of

highly conductive material, for example, aluminum, or its alloys. The surface of the heat sink 1 is divided into two parts by an annular protrusion 5, while the first part 1.1 of the heat sink 1 is fixed in the cavity of the housing 2, and the second part 1.2 is placed in the cavity of the light guide 3 so that between the heat sink 1 and the light guide 3

formed ventilation gap 13 corresponding to the width of the annular stop 16.

 In the embodiment of the lamp with two caps 2, in each of them a cylindrical heat sink 1 is fixed, similar to that shown in Fig. 4, and the light guide 3 is installed between the protrusions 5 of the heat sinks.

 The LEDs are mounted on the board 4, made in the form of a ring placed on the circular protrusion 5 of the cylindrical heat sink 1. In this case, the LEDs are mounted with the possibility of irradiation of the end surface 18 of the light guide 3.

An annular limiter 16 is installed between the end surface of the light guide 3 and the LED board 4, which prevents mechanical contact of the end of the light guide 3 with the LEDs and ensures that the board 4 is clamped to the surface of the protrusion 5 on the heat sink 1. The pressure of the board 4 against the protrusion 5 is created when fixing the fixing cover b, due to the presence of an elastic ring gasket 21 between the fixing cover 5, on the one hand, and the ends of the light guide 3 and heat sink 1, on the other hand.

 The cooling efficiency is achieved, in particular, by creating a convection flow generated during operation of the lamp in the ventilation channel, including the ventilation cavity 14 in the cylindrical heat sink 1, the ventilation cavity 13 between the wall of the heat sink 1 and the light guide 3, communicating with the cavity 13 through the slots 10, a ventilation cavity 15 between the wall 20 of the compartment 12 for accommodating the power source and the heat sink 1, through holes 8 in the housing 2 and through holes 11 in the fixing cover b.

 To seal and compensate for thermal expansion, between the fixing cover b and the ends of the light guide 3 and heat sink 1, a white elastic ring gasket 21 is installed, which is also a reflector of the light flux.

 The fixing cover b is fixed in the holes on the heat sink 1 by means of fixing elastic protrusions.

In the variant with two socles, part of the ventilation duct are openings 8 in the housings 2, cavities 13, 14 of the heat pipe 1 and the light guide 3. The means 9 for connecting to the electric network have a predominantly cylindrical surface. The use of a helical surface complicates the connection to the power supply. An advantage of the claimed technical solution is the effective heat removal from the LEDs and its dispersion from the entire surface of the cylindrical heat sink, due to the good convection flow capturing heated air from all lamp cavities.

Claims

FORMULA

1. An LED lamp with a cylindrical waveguide, comprising: a hollow body of heat-conducting material having a remote portion for securing means for connecting to an electrical network; a hollow cylindrical fiber having a lateral light emitting surface, provided with optical heterogeneity elements and end surfaces at the ends of the fiber, the first of which is placed in the cavity of the casing; a printed circuit board in the form of a ring with LEDs, installed with the possibility of lighting the end surface of the fiber; a fixing cover fixed to the second end of the cylindrical fiber; ventilation channel, including the fiber cavity and through holes in the housing and in

fixing cover;

 h

 means for connecting to the mains, t

mounted on a remote part of the housing, characterized in that

equipped with a hollow cylindrical heat sink, the surface of which is divided into two parts by an annular protrusion on which the printed circuit board is installed,

 the first part of the heat sink is fixed in the housing, while the second part of the heat sink is installed in the cavity of the light guide so that a ventilation gap is formed between the heat sink and the light guide, forming a single convection space with the elements of the ventilation channel,

 the fixing cover is connected to the cylindrical heat sink by elastic clips,

 equipped with an annular limiter installed between the heat sink and the light guide and having an external protrusion located between the surface of the LED board and the end surface of the light guide, preventing mechanical contact between the light guide and the LEDs and ensuring the board is clamped to the protrusion surface on the heat sink, due to the presence of an elastic ring gasket between the fixing cover and the ends of the fiber and heat sink.

2. An LED lamp with a cylindrical waveguide, comprising: a hollow body of heat-conducting material having a remote portion for securing means for connecting to the power grid;

 a hollow cylindrical fiber having a lateral light-emitting surface provided with optical heterogeneity elements and an end surface at the end of the fiber placed in the cavity of the housing;

 a printed circuit board in the form of a ring with LEDs mounted to illuminate the end surface of the fiber;

 a ventilation channel including a fiber cavity and through holes in the housing;

 means for connecting to the mains,

mounted on a remote part of the housing,

 characterized in that

 equipped with a second hollow body,

equipped with two hollow cylindrical heat sinks, the side surface of each of which has an annular protrusion that divides the surface of the heat sink into two parts, the first of which is fixed in one of the housings, and the second is placed in the cavity of the fiber so that between the wall of each heat sink and the surface of the fiber is formed a ventilation gap forming a single convection space with elements of the ventilation duct,

 on each annular protrusion a ring LED board is installed with the possibility of lighting one of the end surfaces of the fiber.

 3. The LED lamp according to paragraph 1 or paragraph 2, characterized in that in the cavity of the cylindrical heat sink there is an electrically isolated compartment for the power source, the walls of which form a cavity with the wall of the cylindrical heat sink.

 4. An LED lamp with a cylindrical waveguide according to paragraph 1 or paragraph 2, characterized in that the cylindrical heat sink is made of aluminum or other material having good thermal conductivity and allows efficient heat removal from the LEDs.

5. LED lamp with a cylindrical light guide according to paragraph 1 or paragraph 2, characterized in that on the wall of the heat sink located in the light guide, one or more cutouts are made to ensure a steady convection flow.

6. LED lamp with a cylindrical light guide according to paragraph 5, characterized in that the cutouts are made in the form of longitudinal sections.

 7. LED lamp with a cylindrical fiber according to paragraph 1 or paragraph 2, characterized in that the inner surface of the fiber is equipped with a reflector made in the form of a cylindrical insert or film, the surface of which has reflective properties.

 8. The LED lamp according to paragraph 1 or paragraph 2, characterized in that the circular protrusion on the cylindrical heat sink is made by plastic deformation of the heat sink wall.

 9. The LED lamp according to paragraph 1 or paragraph 2, characterized in that the cylindrical heat sink is made of heat-conducting tubes of different diameters inserted one into the other, with an annular protrusion formed by the end surface of the wall of the tube of larger diameter.

10. The LED lamp according to paragraph 1 or paragraph 2, characterized in that the circular protrusion on the cylindrical heat sink is made of a heat-conducting ring mounted on the surface of a cylindrical heat sink.

 11. The LED lamp according to paragraph 1 or paragraph 2, characterized in that an annular stopper is installed between the surface of the cylindrical heat sink and the light guide, provided with an external protrusion located on the surface of the LED board and preventing the end face of the light guide from the LED housing and pressing the board against the surface of the heat sink protrusion.

 12. The LED lamp according to paragraph 1, characterized in that a screw cap is used as a means of connecting to the mains.

 13. The LED lamp according to claim 1, characterized in that for sealing and compensating for thermal expansion, an elastic ring gasket with reflective properties is installed between the fixing cover and the end of the fiber.

 14. The LED lamp according to paragraph 2, characterized in that the means for connecting to the mains has a cylindrical surface.