PL219928B1 - Cooling system for LED lamp, especially road lamp - Google Patents

Description

Description of the invention

The subject of the invention is a cooling system for LED lamps, especially road lamps, intended for use in lamps for lighting public roads, as well as for architectural, utility and decorative lighting.

The heat sink, known from the Polish utility model No. 43 083, has three flat surfaces situated in one plane and symmetrically arranged in relation to its axis, in line with the direction of the cooling medium flow, separated by two groups of additional short ribs. Each of these groups consists of an odd number of cooling fins, with the central fins along their entire length terminated with guides that allow the fastening of electrical components and components. The extreme flat surfaces and the side surfaces perpendicular thereto are ended with guides that allow other mechanical structures to be attached to the heat sink. The main cooling surface consists of long cooling fins, the extreme ones ending with guides.

A heat sink for cooling electronic components, known from Polish patent specification No. 204 179, is equipped with thin-walled tubes filled with heat-accumulating PCM material.

The heat sink for use in electronics and computer constructions, known from Polish patent application No. 374 773, is made of copper. The heat sink has a plate-shaped base with a high degree of surface smoothness from the bottom and the column elements connected to it at the top, distinguished by the fact that the column elements with the base form a monolith formed of a homogeneous sintered copper powder, thus constituting a homogeneous mass in terms of chemical composition the body, and said columnar elements have a rough, roughened surface, and the base on the side opposite to that from which the columnar elements protrude has a surface with a high degree of smoothness.

The housing of the electronic device known from the Polish patent specification No. 182 865 includes a flow channel formed between the ribbed wall and the flat cover, separating the cooling air along the ribbing of the wall. The channel is divided into parts by longitudinal partitions, the partitions reaching the side wall ribs cut at an angle, and the ribs, along the entire length of the side wall, gradually extend and enter at an obtuse angle into individual parts of the channel and together with the cover, touching the ribs, create further, smaller flow channels.

The heat sink for electronic elements and components, known from the Polish utility model No. 61 764, has the form of a section section whose cross-section has an external shape similar to the letter Q and which has two parallel triangular grooves along its entire length on the two lower sections of the cross-section. On one of the vertical sections of the cross-section it has a perpendicular boom, at the free end of which there is a vertical groove with a width greater than the thickness of the laminate plate. On this vertical section there is a groove, similar in shape to an inverted T, which groove is parallel to the groove and both grooves extend the entire length of the heat sink.

From the description of the utility model CN No. 201 322 219 a construction of a road lamp is known, which has a housing with radiator fins in the form of plates, directly connected and situated perpendicular to the light matrices. Air spaces allow air to flow across the heatsink fins. A similar construction of a high-power street lamp is presented in the description of the utility model CN No. 201 221 710. The subject of the CN model No. 201 322 219 is also the construction of a PCB and a diagram of the lamp control system.

Lamp cooling systems known from use have fins mounted on the housing, the cooling air flow moves through channels formed between the walls of the fins, and these channels are closed on one side with the lamp housing. These systems are ribbed metal surfaces that are manufactured in one piece.

The essence of the cooling system of the lamp according to the invention consists in that the fins of the heat sink in the form of plates are connected directly and situated perpendicularly to at least two light arrays, each light matrix having an elongated printed circuit board along which light emitting diodes are arranged. Between the ribs and the light arrays, free spaces are created for the free flow of air perpendicular to the arrangement of printed circuit boards with light emitting diodes.

Preferably, the printed circuit boards are PCBs.

PL 219 928 B1

Preferably, the heat sink fin plate on the side of the light arrays has a straight bottom edge, with two light arrays perpendicular to the bottom edge at its ends and along the heat sink.

Preferably, at least one light matrix is placed between the two light arrays.

Preferably, the heat sink fin plate from the side of the luminous matrices onto the lower edge bent on both sides at an obtuse angle, with at least two luminous matrices on a different side of the heat sink perpendicular to the bent side edges of the fin plates along the heat sink.

Preferably, along the heat sink, it has four luminous matrices, two luminous matrices each are mounted on both sides of the curved side edge at an obtuse angle to the bottom edge, perpendicular to the bottom and side edges at the apex of the obtuse angle.

It is advantageous that the lower edge of the fin plate of the heat sink, bent on both sides, passes into the side edges of the fin plates with a broken line or an arc, which has straight sections for the light arrays.

The advantage of the invention is the effective removal of heat from light sources in the form of light-emitting diodes, especially in road luminaires, through multidirectional, including convection, air flow between strongly heating light-emitting diodes. Moreover, the convective airflow through the entire lamp cooling system makes the cooling system small compared to known metal ribbed surfaces and therefore much lighter than the latter.

The subject matter of the invention in the exemplary embodiments is shown in the drawing, in which Fig. 1 shows a LED road lamp with a cooling system, Fig. 2 - an axonometric view of the cooling system, with four light matrices located along the heat sink and perpendicular to the edge of the lower and side rib plates, Fig. 3 - cooling system in a lateral view, with four luminous arrays positioned along the heat sink and perpendicular to the lower and side edges of the fin plate, Fig. 4 - cooling system in an axonometric view, with three luminous arrays positioned along the heat sink and perpendicular to the edge of the lower plate ribs, Fig. 5 - a cooling system in a transverse view with three luminous arrays along the heat sink and perpendicular to the edge of the lower rib plate, Fig. 6 - an axonometric cooling arrangement with three luminous arrays along the heat sink and perpendicular to the edge of the lower rib plate , fig. 7 - the cooling system in the view from Am view, with two luminous arrays along the heat sink and perpendicular to the edge of the lower rib plate, Fig. 8 - axonometric view cooling system, with two luminous arrays along the heat sink and perpendicular to the side edge of the rib plate, transverse, with two luminous matrices located along the heat sink and perpendicular to the side edge of the rib plate, Fig. 10 cooling system with three luminous matrices and with the lower edge of the rib plate bent along an arc containing straight sections for the luminous matrices in an axonometric view, Fig. 11 - layout cooling system with five luminous arrays and the bottom edge of the rib plate curved along a broken line in an axonometric view, Fig. 12 - bottom view of the cooling system with two luminous arrays positioned along the heat sink and perpendicular to the edge of the lower rib plate.

P r z k ł a d 1

The cooling system of the LED lamp, especially the road lamp, has a heat sink 1 made of a material with high thermal conductivity. Directly to the heat sink 1 are mounted printed circuit boards 2, on which light sources 4 are mounted in series in the form of light-emitting diodes 4. The ribs 5 of the heat sink 1 are arranged perpendicularly to four light arrays. Each light matrix has an oblong, rectangular printed circuit board 2 along which light emitting diodes are arranged 4. Between the ribs 5 and the light arrays, free spaces are created for free air flow 3, perpendicular to the arrangement of printed circuit boards 2 with light emitting diodes 4. Air flowing convectionally 3 between the ribs 5 and the light arrays effectively cools the heat sink 1. The rib plate 5 of the heat sink 1 on the side of the light arrays has a bottom edge bent on both sides at an obtuse angle to the bottom edge, perpendicular to the bent edges of the side plates of the ribs 5 along the heat sink 1, four light arrays are mounted with two light arrays mounted from the bottom of the ribs 5 along the lower edges of the ribs 5 at both ends of these edges, and the other two light arrays are mounted along the bent edges of the side plates of the ribs 5, similar to Figure 3.

PL 219 928 B1

P r z k ł a d 2

The cooling system of the LED lamp, especially the road lamp, made as in the first example, with the difference that two light matrices are mounted along the heat sink 1, these matrices are mounted from the bottom of the ribs 5 along the lower edges of the heat sink 1 at both ends of these edges, similar to in Fig. 5.

P r z k ł a d 3

The cooling system of the LED lamp, especially the road lamp, is made as in the first example, with the difference that two light arrays are mounted along the curved side edges of the heat sink 1, similar to Fig. 9.

P r z k ł a d 4

The cooling system of the LED lamp, especially the road lamp, is made as in the first example, with the difference that along the heat sink 1 from the bottom, three light arrays are mounted, with two arrays mounted from the bottom of the ribs 5 along the bottom edges of the heat sink 1 at both ends of these edges, and a third light matrix is mounted between the two, similar to Fig. 7.

P r z k ł a d 5

The cooling system of the LED lamp, especially the road lamp, made as in the second or fourth example, with the difference that the lower edge of the rib plate 5 of the heat sink 1, bent on both sides, passes into the side edges of the rib plates 5 in an arc, with three straight sections for three illuminating matrices similar to Fig. 10.

P r z k ł a d 6

The cooling system of the LED lamp, especially the road lamp, made as in the second or fourth example, with the difference that the lower edge of the rib plate 5 of the heat sink 1, bent on both sides, goes into the side edges of the rib plates 5 with a broken line, with three straight sections for three dies glowing, similar to Fig. 11.

Most often, the cooling system of the LED road lamp has a heat sink 1 made by a magnesium die-cast process with attached light matrices in the form of printed circuit boards 2 made of laminate materials with high thermal conductivity or of PCBs, with conductive and insulating tracks marked on them, on which they are attached by soldering with using tin or soldering pastes or welding, light emitting diodes 4. The light arrays are attached to the ribs 5 of the heat sink 1 by means of glue or screws using thermally conductive pastes for the best possible discharge of heat energy to the heat sink.

Claims (8)

Patent claims A cooling system for an LED lamp, especially a road lamp, comprising flow channels formed between the walls of the heat sink ribs, in which the heat sink ribs in the form of plates are connected directly and situated perpendicularly to at least two light arrays, characterized in that each light matrix has an elongated printed circuit board (2), along which light-emitting diodes (4) are arranged, while between the ribs (5) and the light arrays there are free spaces for free air flow (3) perpendicular to the arrangement of printed circuit boards (2) with light-emitting diodes ( 4). 2. The system according to claim The method of claim 1, characterized in that the printed circuit boards (2) are PCBs. 3. The system according to p. The method according to claim 1, characterized in that the rib plate (5) of the heat sink (1) from the side of the luminous matrices onto the straight lower edge, while two luminous matrices are fixed perpendicular to the lower edge at its ends and along the heat sink (1). 4. The system according to p. The method of claim 3, characterized in that at least one light matrix is provided between the two light arrays. 5. The system according to p. 5. A method according to claim 1, characterized in that the rib plate (5) of the heat sink (1) on the side of the light matrices has a bottom edge bent on both sides at an obtuse angle, perpendicular to the bent edges of the side rib plates (5) along the heat sink (1) there are at least two emitting arrays each on a different side of the heat sink (1). 6. The system according to p. 5. A method according to claim 5, characterized in that it has four luminous matrices along the heat sink (1), two luminous matrices are mounted on both sides of the curved side edge at an obtuse angle to the bottom edge, perpendicular to the bottom and side edges at the apex of the obtuse angle. PL 219 928 B1 7. The system according to p. The method according to claim 5 or 6, characterized in that the lower edge of the rib plate (5) of the heat sink (1), bent on both sides, passes into the side edges of the rib plates (5) with a broken line. 8. The system according to p. 5. A method according to claim 5 or 6, characterized in that the lower edge of the rib plate (5) of the heat sink (1), bent on both sides, extends into the side edges of the rib plates (5) in an arc, with straight sections for the light arrays.