EP2331866A1

EP2331866A1 - Lamp with at least one light-emitting diode

Info

Publication number: EP2331866A1
Application number: EP09783113A
Authority: EP
Inventors: Michael Hemerle
Original assignee: Ceramtec GmbH
Current assignee: Ceramtec GmbH
Priority date: 2008-09-22
Filing date: 2009-09-17
Publication date: 2011-06-15
Also published as: KR20110135851A; RU2011115671A; US20110182074A1; DE102009029535A1; WO2010031810A1; CN102216678A; JP2012503285A; RU2521597C2

Abstract

With consideration to energy savings, conventional illumination elements are being replaced by LEDs to an increasing degree. However, the higher the increase in light output, the higher the increase in losses due to radiated heat. To optimally dissipate the incident heat, it is proposed that in a lamp (1, 30) comprising at least one LED (Light Emitting Diode) (4, 34) as a illumination means, comprising a lamp body with a shield (2, 32, 32a) surrounding the LED and a socket (3, 33, 61) holding the LED, the lamp body of the lamp (1, 30) should be made entirely of a ceramic material.

Description

Lamp with at least one light emitting diode

The invention relates to a lamp having at least one light emitting diode (LED = Light Emitting Diode), which is arranged on a base and is surrounded by a shield-shaped body as a heat sink. The base and the screen 5 may be made of a ceramic material.

From the viewpoint of energy saving, conventional luminous bodies are increasingly being replaced by LEDs. However, the higher the luminous efficacy is increased, the higher the loss due to radiated heat increases. This is especially the case with high power LEDs.

ID For example, an LED with an input power of 4 watts at 1 amp emits a radiant energy of 1, 2 watts as light, 2.8 watts are lost as heat, which must be dissipated. From DE 112006001536 T5 a so-called high-power solid-state luminaire is known. To derive the heat generated by the LED is a metallic reflector with a porous

15 ceramic material deposited, which requires a complex construction.

The object of the invention is to introduce an LED lamp with a simple structure.

The lamp according to the invention consists of a base and a screen which surrounds the at least one LED. The ladder, the anode conductor D and the cathode conductor are accommodated in the base and lead to the surface of the base on the side facing the screen. The LED may have a Surface Mounted Device (SMD) package to solder it to the base with its terminals attached to the conductors. If the LED is wired, the connection of the LED to the anode conductor and the cathode conductor except soldering can also be so5, as will be described below on an embodiment. The screen surrounding the LED has three functions. It protects the LED from damage and its color design influences the color of the emitted light. In the main, however, it serves as a heat sink, ie for heat dissipation of the heat generated by the LED to the ambient air. For enlarging the surface, the screen can have structures distributed over its circumference, such as, for example, ribs whose cross-sections can have any shape. Also, the shape of the screen can be arbitrary. It can be round, for example polygonal, oval or elliptical.

The body of the lamp may be one-piece or two-piece, i. consisting of ID a pedestal with an attached screen. In this case, the screen can be glued to the base or otherwise firmly connected. This design is particularly advantageous when LEDs are to be soldered with SMD housing on the base, because thereby the solder joints are freely accessible before the assembly of base and screen.

15 The material of the lamp must be heat resistant. A particularly suitable material for the lamp is a ceramic material with a good thermal conductivity, for example alumina, glassy or pure, with or without additives, for example Cr ₂ O ₃ , having a thermal conductivity of 20 to 40 W / m ° K, or aluminum nitride with a thermal conductivity of 160 to 200 W / m ° K. Depending on the intended lighting effect, the material may be transparent or translucent, translucent. The breaking strength of the ceramic materials should be between 100 and 1000 MPa.

The basic color of the ceramic material is white or glassy clear. By 5 corresponding, known from the prior art additives to the ceramic material, the ceramic material may also be colored. Combinations of LEDs that emit white or colored light with corresponding ceramic material can produce different color effects be achieved. Furthermore, the screen may have a translucent cover of the LED, which may be clear or colored. The following color combinations are possible:

- The light of the LED has the basic color white, the ceramic material is white 5 or glassy.

- The light of the LED has the basic color white, the ceramic material is colored.

- The light of the LED is colored, the ceramic material is white or glassy.

- The light of the LED is colored, the ceramic material is colored.

ID - The light of the LED has the basic color white, the ceramic material is white or glassy and the cover over the LED is colorless.

- The light of the LED has the basic color white, the ceramic material is white or glassy and the cover over the LED is colored.

- The light of the LED has the basic color white, the ceramic material is 15 colored and the cover over the LED is colorless.

- The light of the LED is colored, the ceramic material is white or glassy and the cover over the LED is colorless.

- The light of the LED is colored, the ceramic material is colored and the cover over the LED is colorless. D - The light of the LED is colored, the ceramic material is colored and the cover over the LED is colored.

The bases of the lamp body can also be equipped as a plug for the production of plug-in connections with corresponding sockets or with threads for screwing into brackets or, in poles covered with terminal poles, in5 lamp sockets.

With reference to embodiments, the invention is explained in detail. Show it: - A -

1 shows a view of an embodiment of the lamp according to the invention with a lamp body made of ceramic material,

FIG. 2 shows a longitudinal section through a two-part lamp body according to FIG. 1 in a perspective view,

FIG. 3 shows the view of the longitudinal section through a two-part lamp body according to FIG. 1,

FIG. 4 a longitudinal section through a two-part lamp body according to FIG. 1 with soldered-on LED in the SMD housing and with cover;

5 shows an embodiment according to FIG. 4 with plug-in connections, FIG. 6 shows a plan view of a lamp base with LED multiple assembly, FIG.

7 shows a longitudinal section through a one-part ceramic body of the lamp for a replaceable, wired LED,

FIG. 8 shows a threaded lamp cap for screwing into a holder;

9 shows a lamp base with standard thread for screwing into a lamp socket, FIG.

FIG. 10 shows a lamp base with strain relief for the connecting conductors.

FIG. 1 shows the photograph of an exemplary embodiment of a lamp 1 according to the invention. The screen 2 and the base 3 form the lamp body and consist of white, translucent ceramic material. The material may also be made of a heat-resistant plastic in low-power and heat-dissipating LEDs. The centrally arranged in the lampshade 2 LED (LED) 4 radiates white light in the present embodiment. From the underside of the base 3, the connecting leads 5 of the LED 4 emerge. The screen 2 has on its circumference evenly distributed cooling fins 5 6, so that the outline of the screen 2 looks at its opening like a gear. The cooling fins are, in particular in high-power LEDs, an advantage to dissipate the heat generated to the ambient air. Your cross section can also take any other possible form such as half round or semi-elliptical. For LEDs with low heat loss, the screen can also be smooth. The screen may also have different shapes, such as oval or polygonal.

FIG. 2 shows a section through the lamp body of the lamp 1 in a perspective view. The section runs in each case through cooling ribs 6. The screen 2 and the base 3 are glued together on their circumference at the adhesive point 7. The base 3 has two channels 8, through which the connection conductors 5, visible in FIG. 1, the anode conductor and the cathode conductor are led to the connection point 9 of the LED 4.

ID Figure 3 shows the view of a longitudinal section through the lamp body of the lamp 1. The section extends on the left and on the right side in each case by a cooling fin 6. In the opening 10 of the screen 2 is a recess 11, in which a cover for protection the LED, not shown, can be used. This cover may for example be made of glass or plastic and, in

15 vote on the color of the LED and the ceramic material, be colored or clear.

Figure 4 shows a longitudinal section through the lamp body of the lamp 1 with soldered LED 4 with SMD housing. The screen is closed by a cover 10a. The color of the cover 10a is selectable according to the desired D color of the light. The LED 4 is shown schematically here. On a substrate 12, for example made of ceramic material, the phosphor layer 13 is applied, which is protected by a sectioned lens 14, for example made of glass. The LED 4 is soldered at the intended location 9 on the solder joints 15 with its anode terminal 16 to the anode conductor 17 and mit5 their cathode terminal 18 to the cathode conductor 19. The connection conductors 5 are guided through the channels 8 in the base 3 up to the solder joints 15 and are there freed from their insulation 20. In order to distinguish between anode and cathode connection, either the connection conductors 5 have different colored insulation or it is attached to the base 3 a corresponding note. For strain relief, the connection conductors 5 may be glued in the channels 8.

FIG. 5 shows an exemplary embodiment of a lamp according to FIG

5 socket 3 in a connector, a plug can be inserted. To the

Inserting into a plug-in connection are solid metal pins instead of elastic conductors

21 inserted as plug contacts for the preparation of the terminal in the base 3. The base 3 itself can be inserted into a plug connection, for example into a wall socket, into a socket of a connection lead

ID or in a socket of a fairy lights having the required external shape, as it is not shown here.

Figure 6 shows a plan view of a base 3 with a multi-populated with LEDs on an enlarged scale compared to the previous illustrations. Features consistent with the previous embodiments are with

15 denoted by the same reference numerals. The embodiment is a schematic representation. There are four LEDs 4 arranged on top of the base 3. In each case, the anode terminals 16 and the cathode terminals 18 are soldered by two adjacent LEDs on a common solder joint 15. The base 3 then contains, as not shown here, either four D connection conductors, two anode conductors 17 and two cathode conductors 19, or in each case two solder joints 15 of the anode terminals 16 and the cathode terminals 18 are formed by conductor tracks on the surface of the base 3, as not shown here, connected to each other, so that the original shape of the base 3 with two channels 8 can be used. FIG. 7 shows a longitudinal section of a further embodiment 30 of the lamp according to the invention. The difference from the preceding embodiments is that the lamp body 31 is in one piece. The screen 32 and the base 33 form a unit. The cut also runs here by the cooling ribs 32a of the screen 32. This embodiment is particularly suitable for wired LEDs 34. For leaded LEDs, the anode terminal 35 and the cathode terminal 36 are led out of the LED body in wire form. In the figure 7, the lens 37 of the schematically illustrated 5 LED 34 is cut and shows the main body 38 with the phosphor layer 39, the anode 40 is connected to the anode terminal 35 and the cathode 41 to the cathode terminal 36.

In the present embodiment, the lamp 30 is designed so that the LED 34 is replaceable. For this purpose, the anode terminal 35 and the

ID cathode terminal 36 each inserted into it in the base 33 inserted and adapted to the terminals tube 42. These tubes 42 stuck in channels 43 and extend continuously from the bottom 44 of the base 33 to the upper end 45 of the base 33. Where the tubes 42 pierce the upper end 45 of the base 33, the openings 46 in the base 33 are conical

15 formed so that the ends 47 of the tubes 42 can be widened correspondingly conical. As a result, they are protected in the base 33 against pulling out when tensile load of the connecting conductor 48. In addition, the insertion of the LED connection wires is facilitated by the conically widened tubes 42. D Before the tubes 42 are inserted into the socket 33 and expanded in the openings 46, the leads 48 are connected to the tubes. For this purpose, the connecting conductors 48 are freed from their insulation 49 and the anode conductor 50 and the cathode conductor 51 are soldered into the corresponding tubes 42 and then inserted into the base 33. To protect against contact metallic bare terminals, the connection conductors 48 can be inserted with their insulation 49 in recesses 52 of the base 33. To increase the security against pulling out the connecting conductors 48 can be additionally glued in these recesses 52. As is known, leaded LEDs have different lengths of lead wires so that the anode and cathode can not be confused. The cathode terminal 36 is shorter than the anode terminal 35. In the present embodiment, the swapping of the terminals of the LED at

5 to prevent insertion into the tubes, the anode conductor 50 and the cathode conductor 51 are each inserted so far into the tubes 42 that at fully inserted into the tubes 42 terminals 35 and 36 and fully resting on the upper end 45 of the base 33 LED 34, the anode terminal 35 against the anode conductor 50 and the cathode terminal 36th

ID against the cathode conductor 51 abuts. If the LED with interchanged terminals inserted into the tubes, the longer anode terminal 35 would encounter the longer cathode conductor 51. The LED would therefore protrude from the upper end 45 of the base 33, which is an indication of the interchanging of the terminals.

A lamp with replaceable LED can also be possible in a version with a plug connection, as shown in FIG. The solid plug contacts 21 would then have to have the anode connection and the cathode connection in the length adapted holes.

In order to facilitate the replacement of an LED 34, the base 33 may have a centrally disposed through bore 53 which terminates below the body 38 of the LED 34. If a correspondingly thin body, for example a wire, is pushed through this bore 53, the anode connection 35 and the cathode connection 36 can be pulled out of the tubes 42. Figure 8 shows an embodiment of a lamp body according to Figure 3, cut, with a base 3, which carries on its outer surface a thread 54 for screwing into a screw socket of a holder, not shown here, for example in a piece of furniture or a display case. The thread 54 can also, as here not shown, be mounted on the base of a one-piece lamp body according to the embodiment of Figure 7. To protect the ceramic material, the thread 54 may be covered with a correspondingly shaped metal sleeve 55.

5 shows in FIG. 9, based on the exemplary embodiments according to FIGS. 4 and 8, a lamp 1 with a lamp base 61, the thread 55 of which is suitable for screwing into standard sockets and which serves for the power supply. Features consistent with the previous embodiments are designated by the same reference numerals. The base 61 is also here with

ID a thread 54 which is surrounded by a correspondingly shaped metallic sleeve 55. In contrast to the sockets according to FIGS. 4 and 8, the base 61 has a centrally arranged channel 62, through which the anode conductor 63 extends and is connected at the solder joint 15 to the anode terminal 16 of the LED 4. At the bottom 64 of the base

15 61, the anode conductor 63 is soldered to a contact plate 65, which makes contact with the corresponding live pole in the socket. The cathode terminal 18 of the LED 4 is connected at the solder joint 15 with the cathode conductor 66. The cathode conductor 66 is led through a correspondingly shaped gap 67 in the base 61 to the outside and is connected at the soldering point 68 with the D sleeve 55 which makes contact in a lamp socket to the corresponding live pole. The design shown here is for connection to a correspondingly poled DC power supply. For connection to an AC mains, the lamp must be equipped with a rectifier circuit, as not shown here. FIG. 10 shows in section a base of a lamp body according to FIGS. 3 or 4, which is equipped with a strain relief 56 for the connection conductors 5. Socket 3 and connecting conductor 5 are surrounded by a correspondingly shaped elastomer, for example rubber, which offers protection against pulling out of the connection conductors 5. The strain relief 56 can For example, serve as part of a fairy lights, not shown here for receiving the lamp body. For better anchoring of the strain relief 56 to the base 3, this can be provided with grooves 57 arranged on its circumference. The two connection conductors 5 can be made

5 of this strain relief 56 are led out either separately, or, as shown here, to a common, surrounded by a common insulation 58 line 59 are summarized. At the strain relief 56 may additionally be an eyelet 60, for example, for hanging or attaching the lamp body, be formed. The strain relief 56 can also, as not here

ID, be mounted on the base of a one-piece lamp body according to the embodiment of Figure 7.

Embodiments of the invention are described below:

1. Inventive lamp, characterized in that the light of the LED (4, 34) is white.

15 2. Inventive lamp, characterized in that the light of the LED (4, 34) is colored.

3. Inventive lamp, characterized in that the ceramic material of at least the screen (2, 32) is colored and that the light of the LED (4, 34) is white. D 4. Inventive lamp, characterized in that the ceramic material of at least the screen (2, 32) is colored and that the light of the LED (4, 34) is colored.

5. Lamp according to the invention, characterized in that the screen (2, 32) has a translucent cover (10a) of the LED (4, 34) which is colorless. 6. Lamp according to the invention, characterized in that the screen (2, 32) has a translucent cover (1 Oa) of the LED (4, 34), which is colored.

7. Inventive lamp, characterized in that the base (3, 33, 5 61) channels (8, 43, 62) for the connection conductors (5, 48, 63) of the LED (4, 34).

8. Inventive lamp, characterized in that the at least one LED (4) has an SMD housing and on the base (3, 61) at the designated location (9) on the solder joints (15) with its anode connection

ID (16) to the anode conductor (17; 63) and with its cathode terminal (18) to the cathode conductor (19; 66) of the connecting conductor (5) is soldered.

9. Inventive lamp, characterized in that the at least one LED (34) is a wired LED and interchangeable.

10. A lamp according to the invention, characterized in that the anode connection (35) and the cathode connection (36) of the LED (34) are respectively inserted into tubes (42) inserted into the base (33) and adapted to the connections, these tubes ( 42) in channels (43) in the base (33) and extending continuously from the bottom (44) of the base (33) to the upper end (45) of the base (33). D 11. A lamp according to the invention, characterized in that where the tubes (42) pierce the upper end (45) of the base (33), the openings (46) of the channels (43) are conical and the ends (47 ) of the tubes (42) are widened conically in accordance with the openings (46). 12. Inventive lamp, characterized in that the anode conductor

(50) and the cathode conductor (51) of the connecting conductor (48) each inserted so far into the tubes (42) and soldered there that when completely in the tubes (42) inserted anode terminal (35) and

5 cathode connection (36) and completely on the upper end (45) of the

Base (33) of adjacent LED (34) of the anode terminal (35) against the anode conductor (50) and the cathode terminal (36) against the cathode conductor

(51) encounters.

13. A lamp according to the invention, characterized in that the base (33) ID a continuous, under the LED (34) ending bore (53) for

Expelling the LED from the tubes (42).

14. Lamp according to the invention, characterized in that the base (3, 61) has a thread (54).

15. Inventive lamp, characterized in that the thread (54) 15 is protected by a correspondingly shaped sheet metal sleeve (55).

16. A lamp according to the invention, characterized in that the sheet-metal sleeve (55) on the base (61) surrounds a thread (54) which serves for screwing into a standardized socket serving for supplying current, that the lower end (64) of the base (61 ) centrally carries a contact plate (65) for making contact with a live pole of the socket and that this contact plate (65) and the sleeve (55) respectively via conductors (63, 66) to the terminals (16, 18) of the LED (4) are connected

17. Inventive lamp, characterized in that the base (3) with a strain relief (56) for the connecting conductor (5) is provided. 18. Lamp according to the invention, characterized in that the strain relief (56) consists of an elastomer.

19. Inventive lamp, characterized in that the strain relief (56) has an eyelet (60).

Claims

claims

1. Lamp having at least one LED (Light Emitting Diode) as a light source, consisting of a lamp body with a surrounding the LED screen and a LED supporting base, characterized in that

5 the lamp body of the lamp (1, 30) completely made of a ceramic

Material exists.

2. Lamp according to claim 1, characterized in that the lamp body of the lamp (1) from the two components screen (2) and base (3, 61) is composed.

ID 3. The lamp as claimed in claim 1, characterized in that the lamp body (31) formed from the shield (32) and the base (33) is integral with the lamp (30).

4. Lamp according to one of claims 1 to 3, characterized in that the screen (2, 32) cooling fins (6, 32a).

5. Lamp according to claim 4, characterized in that the cooling ribs (6, 15 32 a) on the outer circumference of the screen (2, 32) are arranged.

6. Lamp according to one of claims 1 to 5, characterized in that the material of the shield (2, 32) and base (3, 33, 61) existing lamp body of the lamp (1, 30) is a ceramic material.

7. Lamp according to claim 6, characterized in that the ceramic D material has a breaking strength of 100 MPa to 1000 MPa.

8. Lamp according to claim 6 or 7, characterized in that the ceramic material has a thermal conductivity of 20 W / m ° K to 40 W / m ° K.

9. Lamp according to claim 8, characterized in that the ceramic material is alumina.

10. Lamp according to claim 6 or 7, characterized in that the ceramic material has a thermal conductivity of 160 W / m ° K to

5 200 W / m ° K has.

11. Lamp according to claim 10, characterized in that the ceramic material is aluminum nitride.

12. Lamp according to one of claims 1 to 11, characterized in that the ceramic material of at least the screen (2, 32) transparent

ID translucent, translucent.

13. Lamp according to one of claims 1 to 11, characterized in that the ceramic material, at least the screen (2, 32) is transparent.

14. Lamp according to one of claims 1 to 12, characterized in that the ceramic material at least of the screen (2, 32) white or glassy

15 is clear.