RU2540775C1 - Led lamp - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: LED lamp comprises a bulb of transparent material, a replaceable radiating element and a fixture made as an electric holder. The fixture comprises a body and at least one pair of spring contacts designed to be connected to the power supply unit. The replaceable radiating element has the central cooling radiator, which is covered by a flexible printed board from three sides. The printed board has tracks; at that at least one light-emitting diode is installed at the top side. Two lateral sides of the printed board touch spring contacts forming a current-conducting connection between the spring contacts and tracks of the printed board. The lamp comprises at least two lateral cooling radiators, which are connected to the bulb at the one side and to the body at the other side. Two lateral sides of the central cooling radiator and lateral sides of the printed board covering them are crimped between two side cooling radiators thus forming thermal contact of the printed board with the central and side cooling radiators.

EFFECT: improved heat removal, which allows using powerful light-emitting diodes.

21 cl, 5 dwg

Description

The invention relates to the field of semiconductor lighting, and in particular to LED lamps, and can be used for lighting.

LED lamps are an effective source of light, consume little electricity and have a long service life. Their widespread connection to the power supply using a threaded pair is due to the established practice of using vacuum tubes. For an LED lamp, the presence of structural elements that realize a threaded connection is not necessary. The detachable electromechanical connection of the emitting element of the LED lamp with a means for fixing it and connecting it to the power supply network (electrons) can be achieved by translating the emitting element relative to the electrons. When creating such a connection, it is necessary to take into account that the LED is a source of heat, which negatively affects the light characteristics and the life of the LED. This is especially true in the case of using high-power LEDs.

Known LED lamp described in application US 20020149933, containing a number of LEDs with hard leads soldered on two flexible circuit boards mounted on opposite sides of the structural plate so that the LED housings are located on the end of this plate, and their optical axes are directed along the surface of the circuit boards . As an installation product, a mounting support is used, equipped with flexible levers that ensure the retention of the structural plate on the mounting support. The LED board is connected to the power supply using printed or mounted conductors.

A disadvantage of the known solution is the lack of heat dissipation and, as a consequence, the lack of the ability to use high-power LEDs. In addition, the permanent connection of LEDs by desoldering with hard leads increases the complexity of manufacturing the lamp, namely, it complicates the automation of the manufacturing process, which increases the price of the product.

Closest to the claimed invention is the LED lamp described in patent CN 202901965, which contains a flask of transparent material, a replaceable radiating element and fixing means (electrons), including cooling radiators and at least one pair of spring contacts made with the ability to connect to a power source, while the replaceable radiating element has a central radiator, which covers a printed circuit board having tracks on which the LED is mounted. To integrate heat transfer, the LED lamp is equipped with air ducts. This LED lamp is selected as a prototype of the claimed invention.

The disadvantage of the LED lamp of the prototype is the design of cooling radiators and air ducts, which provides insufficient heat dissipation and, as a result, the inability to use powerful LEDs.

The objective of the claimed invention is the creation of an LED lamp with a replaceable radiating element, with reduced manufacturing time and improved heat dissipation due to the presence in the lamp structure of at least two side cooling radiators and a central cooling radiator covered by a flexible printed circuit board, the side cooling radiators being connected via detachable mechanical connections on the one hand with the bulb, and on the other hand with the body of the electroparticle, with two sides of the central p the cooling radiator and the sides of the printed circuit board covering them are sandwiched between two side cooling radiators with the formation of thermal contact of the printed circuit board with the central and side cooling radiators.

The problem is solved by creating an LED lamp containing a bulb made of a transparent material, a replaceable radiating element and fixing means (electrons), and the fixing means (electrons) includes a housing and at least one pair of spring contacts made with the possibility of connection to a power source wherein the replaceable radiating element has a central cooling radiator, which is covered on three sides by a flexible printed circuit board having tracks, on the upper side of which at least m re, one LED, and two sides of the printed circuit board are in contact with the spring contacts with the formation of a conductive connection between the spring contacts and the tracks of the printed circuit board, characterized in that it also contains at least two side cooling radiators, which are connected by detachable mechanical connections on one side with a flask, and on the other hand with a housing, while the two sides of the central cooling radiator and the sides of the printed circuit board covering them are sandwiched between two side cooling radiators to form a thermal contact with a central printed circuit board and with the side cooling radiators.

In a preferred embodiment of the LED lamp, a central cooling radiator is adhered on three sides by a flexible printed circuit board.

In a preferred embodiment of the LED lamp, the sides of the printed circuit board covering opposite sides of the central cooling radiator are in contact with the spring contacts to form a conductive connection between the spring contacts and the tracks of the printed circuit board.

In a preferred embodiment of the LED lamp, two opposite sides of the central cooling radiator and the sides of the printed circuit board covering them are sandwiched between the two side cooling radiators, and a flask of transparent material is placed above the upper side of the printed circuit board on which at least one LED is mounted.

In a preferred embodiment, the LED lamp bulb is made in the form of a hemisphere or hollow half cylinder.

In a preferred embodiment of the LED lamp, the side cooling radiators are made in the form of straight rectangular plates having external cooling protrusions, while the imaginary surface passing through the outer edges of the cooling protrusions of each side radiator has the shape of a half cylinder and the housing is made in the form of a hollow cylinder the upper side of each plate is connected to the bulb, and the lower side is connected to the base of the hollow cylinder, in which a pair of spring contacts are placed.

In a preferred embodiment of the LED lamp, the side cooling radiators are made in the form of straight rectangular plates with fins, and the body is made in the form of a rectangular plate with a U-shaped cross section curved along the length, and two plugs inserted into it along the edges of the caps, and a pair of spring loaded inside the rectangular plate contacts, wherein each of the two straight rectangular plates of the side radiators is connected to the bulb by the upper side and connected to the corresponding curved side by the lower side rectangular plate casing.

In a preferred embodiment of the LED lamp, the side cooling radiators are electrically isolated from each other.

In a preferred embodiment of the LED lamp, the side cooling radiators are not electrically isolated from each other and are made of non-conductive material.

In a preferred embodiment of the LED lamp, the outer surface of the side cooling radiators has cooling protrusions.

In a preferred embodiment, the LED lamp detachable mechanical connection is made in the form of a protrusion and recesses that are in mechanical engagement with each other.

In a preferred embodiment of the LED lamp, the central cooling radiator is in the form of a parallelepiped.

In a preferred embodiment of the LED lamp, the cooling radiators are made of heat-conducting material.

In a preferred embodiment of the LED lamp, the spring contacts are capable of closing together in the absence of a replaceable radiating element, while providing circuit closure and power supply to the remaining lamps included in the circuit.

In a preferred embodiment, the LED lamp, the circuit board is made in the form of a bent U-shaped plate.

In a preferred embodiment, the LED lamp bulb is made of translucent or translucent material with the ability to protect the printed circuit board and LEDs from contact.

In a preferred embodiment, the LED lamp contains several LEDs, with all the internal connections of the LEDs being made automatically when changing the topology of a single one-sided printed circuit board.

In a preferred embodiment of the LED lamp, a phosphor or a mixture of phosphors is implanted into the material of the flask, the LED lamp containing blue or cold white LEDs.

In a preferred embodiment of the LED lamp, the entire volume inside the bulb is filled with transparent silicone.

In a preferred embodiment of the LED lamp, a phosphor is implanted in the silicone.

In a preferred embodiment of the LED lamp, a phosphor of one type is implanted in silicone, and a phosphor of another type is implanted in the material of the bulb.

For a better understanding of the claimed invention the following is a detailed description with the corresponding graphic materials.

Figure 1. Images of an embodiment of an LED lamp with a single LED and an electro-cartridge housing made in the form of a hollow cylinder: a sectional side view of the LED lamp according to the invention.

Figure 2. Images of an embodiment of an LED lamp with a single LED and an hollow cylinder-shaped electrocart housing: image of LED lamp elements in isometric view, image of LED lamp in isometric view, front view of the LED lamp, side view of the LED lamp, top view of the LED lamp, view in sectional side view of the LED lamp according to the invention.

Figure 3. Images of an embodiment of an LED lamp with one LED and an electron cartridge housing made in the form of two rectangular plates with a U-shaped cross section bent along the length, inserted one into another: image of LED lamp elements in isometric projection, image of LED lamp in isometric projection, front view of LED lamps, side view of the LED lamp, top view of the LED lamp, sectional side view of the LED lamp according to the invention.

Figure 4. Images of an embodiment of an LED lamp with several LEDs and a housing made in the form of a rectangular plate with a U-shaped cross section curved along the length and two plugs inserted into it at the edges: isometric view of the elements of the LED lamp, front view of the LED lamp, side view of the LED lamp lamps, top view of the LED lamp, side sectional view of the LED lamp according to the invention.

Figure 5. Isometric view of an embodiment of an LED lamp with several LEDs and a housing made in the form of a rectangular plate with a U-shaped cross section curved along the length and two plugs inserted into it at the edges according to the invention.

Items:

1 - housing;

2 - flask;

3 - cooling protrusion;

4 - LED;

5 - flexible printed circuit board;

6 - central cooling radiator;

7 - side cooling radiator;

8 - spring contact.

Consider in detail the embodiments of the claimed LED lamp. In all embodiments (Figs. 1-5), the claimed LED lamp comprises a bulb 2 made of a transparent material, a replaceable radiating element, and a fixing means (electrons). The fixing means (electrons) includes a housing 1 and at least one pair of spring contacts 8, made with the possibility of connecting to a power source. The replaceable radiating element includes a central cooling radiator 6, which on three sides is covered by a flexible printed circuit board 5 having tracks. At least one LED 4 is mounted on the upper side of the flexible circuit board 5. The two sides of the circuit board 5 are in contact with the spring contacts 8 to form a conductive connection between the spring contacts 8 and the tracks of the circuit board 5. Two side cooling radiators 7 are connected by detachable mechanical connections on the one hand with a bulb 2, and on the other hand with an electron cartridge case 1, while the two sides of the central cooling radiator 6 and the sides of the printed circuit board covering them 5 clamped between the two lateral cooling radiators 7 to form a thermal contact with the circuit board 5 and 6 with the central side cooling radiators 7.

The printed circuit board 5 is glued to the central cooling radiator 6. The sides of the printed circuit board 5 covering opposite sides of the central cooling radiator 6 are in contact with the spring contacts 8 to form a conductive connection between the spring contacts 8 and the tracks of the printed circuit board 5. The central cooling radiator 6 is made in the form of a parallelepiped. The central cooling radiator 6 and the side cooling radiators 7 are made of heat-conducting material. The spring contacts 8 are made with the possibility of short circuiting among themselves in the absence of a replaceable radiating element, while ensuring the closure of the electric circuit and the power supply of the remaining lamps included in the electric circuit. The flask 2 is made of translucent or translucent material with the ability to protect the printed circuit board 5 and the LEDs 4 from contact. In an embodiment of a lamp containing several LEDs 4, all internal connections of LEDs 4 are made automatically when changing the topology of a single one-sided printed circuit board 5. A phosphor or a mixture of phosphors can be implanted into the material of bulb 2, and the LED lamp must contain blue or cold white LEDs 4 .

Consider an embodiment of the claimed LED lamp with one LED 4 and the housing 1, made in the form of a hollow cylinder (Figure 2). In this embodiment, the flask 2 is made in the form of a hemisphere. The side cooling radiators 7 are made in the form of straight rectangular plates having external cooling protrusions 3. The imaginary surface passing through the outer edges of the cooling protrusions 3 of each side radiator 7 has the shape of a half cylinder. The upper side of each rectangular plate is connected to the bulb 2, and the lower side is connected to the base of the hollow cylinder, in which a pair of spring contacts 8 are placed.

Consider the embodiment of the LED lamp with one LED 4 and the housing 1 of the electric cartridge, made in the form of two curved along the length of a rectangular plate with a U-shaped cross-section, inserted one into the other (Figure 3). In this embodiment, the flask 2 is made in the form of a hollow half-cylinder. The side cooling radiators 7 are made in the form of straight rectangular plates, and the housing 1 of the electric cartridge is made in the form of rectangular plates bent along the length of a U-shaped cross-section, into which radiators are inserted, in which a pair of spring contacts are placed 8. Each of the two straight rectangular plates of the side radiators 7, the upper side is connected to the bulb 2, and the lower side is connected to the corresponding upper side of the curved rectangular plate of the housing 1. The outer surface of the two side cooling radiators 7 is covered with oh by the projecting projections 3. The sides of all the plates of the side cooling radiators 7 are connected to the housing 1.

A possible embodiment of the claimed LED lamp with several LEDs 4 and the housing 1 of the electric cartridge, made in the form of a curved along the length of a rectangular plate with a U-shaped cross-section, and two plugs inserted into it at the edges (Figs. 4, 5). In this embodiment, the two sides of the central cooling radiator 6 and the sides of the printed circuit board 5 covering them are pressed against the two side cooling radiators 7, while the side cooling radiators 7 are electrically isolated from each other.

Although the above-described embodiments of the proposed invention have been set forth to illustrate the proposed invention, it is clear to those skilled in the art that various modifications, additions and substitutions are possible without departing from the scope and meaning of the proposed invention disclosed in the attached claims.

Claims (21)

1. An LED lamp comprising a bulb made of a transparent material, a replaceable radiating element and fixing means in the form of an electric cartridge, the fixing means including a housing and at least one pair of spring contacts configured to be connected to a power source, while the replaceable radiating element has a central cooling radiator, which on three sides is covered by a flexible printed circuit board having tracks, on the upper side of which at least one LED is installed, and two sides of the printed circuit the boards are in contact with the spring contacts with the formation of a conductive connection between the spring contacts and the tracks of the printed circuit board, characterized in that it also contains at least two side cooling radiators, which are connected via detachable mechanical connections on the one hand to the bulb and, on the other hand, to the body, the two sides of the central cooling radiator and the sides of the printed circuit board covering them are sandwiched between the two side cooling radiators with the formation of thermal PCB contact with central and side cooling radiators. 2. The LED lamp according to claim 1, characterized in that a flexible printed circuit board is glued on three sides to the central cooling radiator. 3. The LED lamp according to claim 1, characterized in that the sides of the printed circuit board covering opposite sides of the central cooling radiator are in contact with the spring contacts to form a conductive connection between the spring contacts and the tracks of the printed circuit board. 4. The LED lamp according to claim 1, characterized in that the two opposite sides of the central cooling radiator and the sides of the printed circuit board covering them are sandwiched between two side cooling radiators, and on the upper side of the printed circuit board on which at least one LED is mounted placed a flask of transparent material. 5. The LED lamp according to claim 1, characterized in that the bulb is made in the form of a hemisphere or hollow half-cylinder. 6. The LED lamp according to claim 1, characterized in that the side cooling radiators are made in the form of straight rectangular plates having external cooling protrusions, while the imaginary surface passing through the outer edges of the cooling protrusions of each side radiator has the shape of a half cylinder, and the body is made in the form of a hollow cylinder, with the upper side of each plate connected to the bulb, and the lower side connected to the base of the hollow cylinder, in which a pair of spring contacts is placed. 7. The LED lamp according to claim 1, characterized in that the side cooling radiators are made in the form of straight rectangular plates with fins, and the body is made in the form of a rectangular plate with a U-shaped cross section curved along the length, and two plugs inserted into it at the edges, moreover, a pair of spring contacts are placed inside the rectangular plate, while each of the two straight rectangular plates of the side radiators is connected to the bulb by the upper side, and the curved rectangular side is connected to the corresponding lateral side body plates. 8. The LED lamp according to claim 1, characterized in that the side cooling radiators are electrically isolated from each other. 9. The LED lamp according to claim 1, characterized in that the side cooling radiators are not electrically isolated from each other, but are made of non-conductive material. 10. The LED lamp according to claim 1, characterized in that the outer surface of the side cooling radiators has cooling protrusions. 11. The LED lamp according to claim 1, characterized in that the detachable mechanical connection is made in the form of a protrusion and a recess, entering into mechanical engagement with each other. 12. The LED lamp according to claim 1, characterized in that the central cooling radiator is made in the form of a parallelepiped. 13. The LED lamp according to claim 1, characterized in that the cooling radiators are made of heat-conducting material. 14. The LED lamp according to claim 1, characterized in that the spring contacts are configured to close together in the absence of a replaceable radiating element, while providing circuit closure and power to the remaining lamps included in the circuit. 15. The LED lamp according to claim 1, characterized in that the printed circuit board is made in the form of a bent U-shaped plate. 16. The LED lamp according to claim 1, characterized in that the bulb is made of translucent or translucent material with the ability to protect the circuit board and LEDs from touching. 17. The LED lamp according to claim 1, characterized in that it contains several LEDs, while all the internal connections of the LEDs are carried out automatically when changing the topology of a single one-sided printed circuit board. 18. The LED lamp according to claim 1, characterized in that a phosphor or a mixture of phosphors is implanted in the material of the bulb, while the LED lamp contains blue or cold white LEDs. 19. The LED lamp according to claim 1, characterized in that the entire volume inside the bulb is filled with transparent silicone. 20. The LED lamp according to claim 19, characterized in that a phosphor is implanted in the silicone. 21. The LED lamp according to claim 19, characterized in that a phosphor of one type is implanted into the silicone, and a phosphor of another type is implanted into the material of the bulb.

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