RU2497041C2 - Assembly method of light-emitting-diode lamp, and light-emitting-diode lamp (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: according to the method, side cutouts (4) (SC) are preliminarily made on end faces of radiator (1) (R). Then, on R (1) there fixed is printed-circuit board (2) (PCB) with radioelectronic elements (5) and electric inputs (7), which are mounted on it. After that, on radiator (1) there installed is light-passing part (3), and then, bases (6) are installed on both sides of the lamp housing. With that, electric inputs (7) of printed-circuit board (2) are partially inserted into outputs (8) of bases (6); then, bases (6) are brought to the lamp face, and bases (6) are turned through the specified angle. As per the first version, light-emitting-diode lamp includes radiator (1), printed-circuit board (2), light-passing part (3) and bases (6) arranged on both faces of the lamp. Radiator surface intended for attachment of PCB (2) is flat and plain, and side cutouts (4) are made on radiator (1) faces. As per the second version, light-emitting-diode lamp differs by the fact that radiator is made in the form of a thin-wall tube; besides, side cutouts are made on faces of flat part of the radiator.

EFFECT: providing reduction of labour intensity of the method with simultaneous improvement of heat removal from LEDs and providing isolation of electric lamp inputs from the radiator.

25 cl, 20 dwg

Description

The field of technology.

The claimed group of inventions relates to electrical engineering, namely to lighting technology using light emitting diodes (LEDs). The inventive method of assembling an LED lamp and an LED lamp can be used in the manufacture of LED lamps for lighting and replacing discharge lamps. The inventive LED lamp can be used to replace gas discharge lamps in the reconstruction of lighting systems with minor changes associated with switching.

The prior art.

A known method of manufacturing a light tube (RF patent No. 84504 for a utility model, IPC F21S 4/00, 2009 [1]) consists in the fact that inside the case of a transparent heat-shrinkable material, a board is installed with LEDs and metal plates that provide the functions of radiators.

The disadvantage of this method [1] is the complexity of installing a large number of metal plates.

The specified method of manufacturing a light tube is the closest to the claimed invention. Therefore, it is adopted as a prototype of the proposed method for assembling an LED lamp.

Known light tube [1] made of optically transparent heat-shrinkable material, divided into upper and lower halves of a printed circuit board sealed along its longitudinal axis with LEDs placed on it in the lower part of the tube. Moreover, opposite each LED located in the lower half of the light tube, metal plates are fixed as radiators. From the ends of the lamp are installed socles.

The disadvantage of this analogue [1] is the insufficient heat removal from the LEDs. The heat removed from the circuit board is dissipated in the upper half of the light tube. With insufficient air circulation in the upper half of the tube, the LEDs on the board overheat and, as a result, reduce the life of the light tube.

The specified light tube [1] is the set of essential features the closest device of the same purpose to the claimed invention. Therefore, it is adopted as a prototype of the inventive LED lamp.

Disclosure of the invention.

The technical result provided by the claimed method of assembling an LED lamp is to reduce the complexity of the method while improving heat sink from the LEDs and providing insulation of the electrical inputs of the lamp from the radiator.

The technical result provided by the inventive LED lamp according to options 1 and 2, is to improve the heat sink from the LEDs and the simultaneous isolation of the electrical inputs of the lamp from the radiator.

The essence of the proposed method for assembling an LED lamp is as follows. At the ends of the radiator, side cutouts are preliminarily performed. Then, a printed circuit board with electronic components and electrical inputs mounted on it is mounted on the radiator. After that, the light transmitting part is installed on the radiator. After installing the light transmitting part on the radiator, socles are installed on both sides of the lamp housing. In this case, the electrical inputs of the printed circuit board are partially inserted into the terminals of the plinths, then the plinths are brought to the end of the llama, and the plinths are rotated by a predetermined angle.

The printed circuit board is preferably fixed to the radiator using double-sided adhesive tape, the base of which is dielectric and the thickness of the base is not more than 0.25 mm.

The installation of the light transmitting part on the radiator is preferably carried out by placing the sides of the light transmitting part in the grooves of the radiator.

After the electrical inputs of the printed circuit board are partially inserted into the terminals of the sockets, the sockets are preferably brought to the end of the llama not completely, and then the sockets are rotated through an angle of 90 °, at the same time bringing them all the way to the end of the lamp.

After the plinths are installed, parts of the electrical inputs of the printed circuit board that extend beyond the terminals of the base are predominantly cut off.

After installing the plinths, the terminals of the plinths are preferably crimped.

The essence of the inventive LED lamp according to option 1 is that the LED lamp contains a radiator, a printed circuit board, a light transmitting part and socles located at both ends of the lamp. In this case, the printed circuit board is mounted on the radiator, and the surface of the radiator intended for mounting the printed circuit board is made flat and smooth, and side cutouts are made on the ends of the radiator.

The radiator is preferably made of aluminum.

The radiator can be made in the form of a part of the cylinder formed by the section of the cylinder by a plane parallel to the axis of the cylinder.

The printed circuit board is mainly made of PCB and mounted on the surface of the radiator with double-sided adhesive tape, the base of which is dielectric, and the thickness of the base is not more than 0.25 mm.

The light transmitting part can be made in the form of a cylindrical trough, while the light transmitting part is mainly made of plastic or glass.

The radiator is preferably provided with gutters, and the light transmitting part is respectively provided with sides.

On the outer surface of the radiator, ribs are preferably made.

The radiator may contain cavities.

From each of the two ends, the printed circuit board is preferably equipped with two electrical inputs, the electrical inputs located on one end made in the form of a single wire soldered to the platform on the printed circuit board near its middle.

From each of the two ends, the printed circuit board can be equipped with one electrical input, while the conclusions of the base are electrically connected to each other inside the base.

The essence of the inventive LED lamp according to option 2 is that the LED lamp contains a radiator, a printed circuit board, a light transmitting part and socles located at both ends of the lamp. In this case, the printed circuit board is mounted on the radiator, and the surface of the radiator intended for mounting the printed circuit board is made flat and smooth. In this case, the radiator is made in the form of a thin-walled tube, while side cutouts are made at the ends of the flat part of the radiator.

The radiator cross-section is preferably a circle segment.

On the cylindrical part of the outer surface of the radiator can be made ribs.

Side cutouts can be made in the form of a semicircle.

Side cutouts can be made in a rectangular shape.

The printed circuit board is mainly made of PCB and mounted on the surface of the radiator with double-sided adhesive tape, the base of which is dielectric.

Each base is predominantly equipped with two leads, and the leads are made mainly in the form of tubes fixed in the base housing on a dielectric holder.

From each of the two ends, the printed circuit board is preferably equipped with two electrical inputs, the electrical inputs located on one end made in the form of a single wire soldered to the platform on the printed circuit board near its middle.

From each of the two ends, the printed circuit board can be equipped with one electrical input, while the conclusions of the base are electrically connected to each other inside the base.

A brief description of the drawings.

Figure 1 shows a radiator with cutouts made to its entire height; figure 2 is a diagram of the fixing of the printed circuit board and the light transmitting part on the radiator, side view; figure 3 - mount radiator and light transmitting part; figure 4 is a diagram of the positioning of the socles relative to the lamp, top view; figure 5 - installation diagram of the socles on both sides of the lamp housing; figure 6 - cutouts of the radiator, made in the form of a part of the cylinder; Fig.7 - cutouts of a radiator made of a rectangular shape; Fig. 8 is a diagram of a LED lamp according to embodiment 1; Fig.9 is a section aa of Fig.8; figure 10 is a section aa of Fig.8 according to example 3 of option 1; 11 is a section aa of Fig.8 according to example 4 of option 1; Fig - diagram of a LED lamp according to example 5 of option 1, side view; Fig. 13 is a side view of the lamp of the LED example 6 of embodiment 1; Fig.14 is a diagram of a LED lamp according to example 7 of option 1, side view; Fig - scheme of a LED lamp according to option 2; Fig.16 is a section bb In Fig.15 according to example 4 of option 2; Fig - section EE Fig; Fig. 18 shows a fastening of a radiator and a light transmitting part according to embodiment 2; Fig.19 is a section EE Fig.15 according to example 3 of option 2; Fig.20 is a section bb In Fig.15 according to example 5 of option 2.

The implementation of the invention.

In the inventive method of assembling an LED lamp at the ends of the radiator (1), side cutouts (4) are preliminarily performed (Fig. 1). In this case, the radiator (1) is made in the form of a part of the cylinder formed by the section of the cylinder by a plane parallel to the axis of the cylinder. The radiator (1) is made of a heat-conducting material, preferably aluminum. The surface of the radiator (1), intended for mounting the printed circuit board (2), is made flat and smooth.

Then, a printed circuit board (2) is mounted on the radiator (1) with the electronic components (5) mounted on it and the electrical inputs (7) (Fig. 2). The printed circuit board (2) can be mounted on the radiator (1) using double-sided adhesive tape, the base of which is dielectric, and the thickness of the base is not more than 0.25 mm.

Then, a light transmitting part (3) is installed on the radiator (1). To hold the light transmitting part (3) on the radiator (1), the latter is equipped with grooves (9), and the light transmitting part (3) is provided with sides (10) (Fig. 3).

Then, from both ends of the lamp, plinths (6) are installed (Fig. 4). Sockets (6) are designed to connect the LED lamp to power sources. When installing the plinths (6), the electrical inputs (7) soldered to the printed circuit board (2) are partially inserted into the terminals (8) of the plinth (6). The mentioned conclusions (8) of each socle (6) are made mainly in the form of tubes fixed in the housing of the socle (6) on a dielectric holder.

Then the plinths (6) are not brought to the end of the llama to the stop (Fig. 5). After that, the plinths (6) are turned by a predetermined angle, mainly equal to 90 °, at the same time bringing them all the way to the end of the lamp. When turning the socles (6) and bringing them all the way to the end of the lamp, the electrical inputs (7) are bent in the direction of rotation at an angle to the surface of the printed circuit board (2). In this case, one of the sections of the electrical inputs (7) is located in the region of the side cutout (4) at the end of the radiator (1). This ensures the exclusion of electrical contact between the inputs (7) and the radiator (1).

In this case, the side cutouts (4) are made so that when installing and turning the base (6), its terminals (8) are located within the side cutout (4) (within the cross section of the side cutout (4) with a plane perpendicular to the LED lamp).

Cutouts (4) can be made to the entire height of the radiator (1) perpendicular to the plane of attachment of the printed circuit board (2) (Fig. 1). While the cutouts (4) perform a depth less than the thickness N of the socles (6) (figure 4).

The cutouts (4) can also be made in the form of a part of the cylinder (Fig.6) or rectangular shape (Fig.7).

After installing the plinths (6), the parts of the electrical inputs (7) protruding beyond the conclusions (8) of the plinth (6) are cut off. The terminals (8) can be crimped to provide better contact between the electrical inputs (7) and the terminals (8) of the base (6).

In the inventive method of assembling an LED lamp, the claimed technical result: "reducing the complexity of the method while improving heat sink from the LEDs and ensuring the insulation of the electrical inputs of the lamp from the radiator" is achieved due to the fact that lateral cutouts are preliminarily performed on the ends of the radiator. Then, a printed circuit board with electronic components and electrical inputs mounted on it is mounted on the radiator. After that, the light transmitting part is installed on the radiator. After installing the light transmitting part on the radiator, socles are installed on both sides of the lamp housing. In this case, the electrical inputs of the printed circuit board are partially inserted into the terminals of the plinths, then the plinths are brought to the end of the llama, and the plinths are rotated by a predetermined angle.

The LED lamp according to option 1 (Fig. 8, 9) contains a radiator (1), a printed circuit board (2), a light transmitting part (3) and socles (6).

The radiator (1) is made in the form of a part of the cylinder formed by the section of the cylinder by a plane parallel to the axis of the cylinder. The radiator (1) is made of a heat-conducting material, preferably aluminum. The surface of the radiator (1), intended for mounting the printed circuit board (2), is made flat and smooth. In order to eliminate the electrical contact of the conductors of the printed circuit board (2) with the radiator (1), side cutouts (4) are made at the ends of the radiator (1). The radiator (1) is designed to remove heat from the printed circuit board (2) with the mounted electronic components (5).

The printed circuit board (2) is a plate made of a dielectric, mainly PCB. On the first side of the printed circuit board (2) there are electrical conductors connecting the pads intended for installation (soldering) of the electronic components (5), including LEDs. On the second side, polygons are made, electrically connected to the sites and / or conductors on the first side through metallized holes. The second side of the printed circuit board (2) is fixed on a flat part of the surface of the radiator (1) using double-sided adhesive tape (6). The base of the double-sided adhesive tape (6) is dielectric, which provides reliable electrical insulation of the circuit of the printed circuit board (2) from the radiator (1). From each of the two ends of the printed circuit board (2), one or two electrical inputs (7) can be placed that electrically connect the pads of the printed circuit board (2) with the terminals (8) of the base (6). The inputs (7) are made of wire, the thickness of which is sufficient to pass the current consumption of the LED lamp and so that the wire does not bend under its own weight in the area from the printed circuit board (2) to the output (8).

The side cutouts (4) are made so that the terminals (8) of the base (6) and the conductors (7) connecting these leads (8) to the printed circuit board (2) are located inside the side cutout (4).

The light transmitting part (3) is made in the form of a cylindrical gutter, preferably of plastic or glass. The light transmitting part (3) mounted on the radiator (1) form a cylindrical side surface of the LED lamp. To hold the light transmitting part (3) on the radiator (1), the latter is equipped with grooves (9), and the light transmitting part (3) is provided with sides (10) (Fig. 3).

Sockets (6) are placed on both ends of the lamp and are designed for additional fixation of the radiator (1) and the light transmitting part (3), as well as for supplying power to the LED lamp. Each base (6) is equipped with two leads (8). Mentioned conclusions (8) are made mainly in the form of tubes fixed in the base / plinth housing (6) on a dielectric holder.

Examples of specific performance of the LED lamp.

Example 1. At each of the two ends, the printed circuit board (2) is equipped with two electrical inputs (7). In this case, the electrical inputs (7) located on one end are made in the form of a single wire soldered to the platform on the printed circuit board (2) near its middle.

Example 2. From each of the two ends of the printed circuit board (2) is equipped with one electrical input (7). In this case, the conclusions (8) of the base (6) are electrically interconnected inside the base (6).

Example 3. In order to increase the heat sink area of the radiator (1), ribs (11) are made on the outer surface of the radiator (1) (Fig. 10).

Example 4. In order to reduce the consumption of material of the radiator, the radiator (1) contains cavities 12 (11).

Example 5. Cutouts (4) are made to the entire height of the radiator (1) perpendicular to the plane of attachment of the printed circuit board (2) (Fig. 12). In this case, the cutouts (4) are made with a depth less than the thickness H of the socles (6) (Fig. 4).

Example 6. The cutouts (4) are made in the form of a part of the cylinder (Fig.6, 13).

Example 7. The cutouts (4) are rectangular in shape (Fig. 7.14).

The implementation of the structural elements of the claimed invention is not limited to the above examples.

When the LED lamp according to option 1 is turned on, the power supply is supplied to the terminals of the base (6) with the electrical inputs (7) located in them, which then goes to the radio-electronic components (5) of the printed circuit board (2). Moreover, some inputs (7) of the printed circuit board (2) contain sections located in the region of the side cutouts (4). This ensures electrical insulation of the inputs (7) of the printed circuit board (2) from the radiator (1). During operation of the LED lamp, the LEDs (5) emit light and dissipate heat, and other electronic components (5) dissipate heat. The heat generated during the operation of the electronic components (5) is removed through the printed circuit board (2) and the radiator (1) to the external environment.

The use of the inventive LED lamp is to install it in an appropriate cartridge lighting system. The inventive LED lamp can be installed instead of a discharge lamp. This additionally requires reconnection of conductors that are suitable for the cartridge, associated with the disconnection of the elements that ensure the operation of the gas discharge lamp (chokes, ballasts and ballasts), and connecting the claimed LED lamp directly to the power supply.

Thus, from the foregoing, it follows that in the inventive LED lamp according to option 1, the claimed technical result: "improving heat dissipation from LEDs and simultaneous isolation of the electrical inputs of the lamp from the radiator" is achieved due to the fact that the LED lamp contains a radiator, a printed circuit board, a light transmitting part and socles placed at both ends of the lamp. In this case, the printed circuit board is mounted on the radiator, and the surface of the radiator intended for mounting the printed circuit board is made flat and smooth, and side cutouts are made on the ends of the radiator.

The LED lamp according to embodiment 2 (FIGS. 15, 16, 17) comprises a radiator (1), a printed circuit board (2), a light transmitting part (3), and socles (6).

The radiator (1) is designed to remove heat from the printed circuit board (2) with the mounted electronic components (5). The radiator (1) is made in the form of a thin-walled tube. The cross section of the radiator (1) is, in essence, a segment of a circle. The radiator (1) is made of a heat-conducting material, preferably aluminum. The flat part of the surface of the radiator (1) is designed for mounting the printed circuit board (2) and is made smooth. In order to eliminate the electrical contact of the conductors of the printed circuit board (2) with the radiator (1), side cutouts (4) are made at the ends of the flat part of the radiator (1).

The printed circuit board (2) is a plate made of a dielectric, mainly PCB. On the first side of the printed circuit board (2) there are electrical conductors connecting the pads intended for installation (soldering) of the electronic components (5), including LEDs. On the second side, polygons are made, electrically connected to the sites and / or conductors on the first side through metallized holes. The second side of the printed circuit board (2) is fixed on a flat part of the surface of the radiator (1) using double-sided adhesive tape (6). The base of the double-sided adhesive tape (6) is dielectric, which provides reliable electrical insulation of the circuit of the printed circuit board (2) from the radiator (1). From each of the two ends of the printed circuit board (2), one or two electrical inputs (7) can be placed that electrically connect the pads of the printed circuit board (2) with the terminals (8) of the base (6). The inputs (7) are made of wire, the thickness of which is sufficient to pass the current consumption of the LED lamp and so that the wire does not bend under its own weight in the area from the printed circuit board (2) to the output (8).

The light transmitting part (3) is made in the form of a cylindrical gutter, preferably of plastic or glass. The light transmitting part (3) mounted on the radiator (1) form a cylindrical side surface of the LED lamp. To hold the light transmitting part (3) on the radiator (1), the latter is equipped with grooves (9), and the light transmitting part (3) is equipped with sides (10) (Fig. 18).

Sockets (6) are placed on both ends of the lamp and are designed for additional fixation of the radiator (1) and the light transmitting part (3), as well as for supplying power to the LED lamp. Each base (6) is equipped with two leads (8). Mentioned conclusions (8) are made mainly in the form of tubes fixed in the base / plinth housing (6) on a dielectric holder.

Examples of specific performance of the LED lamp.

Example 1. At each of the two ends, the printed circuit board (2) is equipped with two electrical inputs (7). In this case, the electrical inputs (7) located on one end are made in the form of a single wire soldered to the platform on the printed circuit board (2) near its middle.

Example 2. From each of the two ends of the printed circuit board (2) is equipped with one electrical input (7). In this case, the conclusions (8) of the base (6) are electrically interconnected inside the base (6).

Example 3. In order to increase the heat sink area of the radiator (1), ribs (11) are made on the cylindrical part of the outer surface of the radiator (1) (Fig. 19).

Example 4. The cutouts (4) are made in the form of a semicircle (Fig. 16).

Example 5. The cutouts (4) are rectangular (Fig. 20).

The implementation of the structural elements of the claimed invention is not limited to the above examples.

When the LED lamp according to option 2 is turned on, the power supply is supplied to the terminals of the base (6) with the electrical inputs (7) located in them, which then goes to the radio-electronic components (5) of the printed circuit board (2). Moreover, some inputs (7) of the printed circuit board (2) contain sections located in the region of the side cutouts (4). This ensures electrical insulation of the inputs (7) of the printed circuit board (2) from the radiator (1). During operation of the LED lamp, the LEDs (5) emit light and dissipate heat, and other electronic components (5) dissipate heat. The heat generated during the operation of the electronic components (5) is removed through the printed circuit board (2) and the radiator (1) to the external environment.

The use of the inventive LED lamp is to install it in an appropriate cartridge lighting system. The inventive LED lamp can be installed instead of a discharge lamp. This additionally requires reconnection of conductors that are suitable for the cartridge, associated with the disconnection of the elements that ensure the operation of the gas discharge lamp (chokes, ballasts and ballasts), and connecting the claimed LED lamp directly to the power supply.

Thus, from the foregoing, it follows that in the inventive LED lamp according to embodiment 2, the claimed technical result: "improving heat dissipation from LEDs and simultaneous isolation of the electrical inputs of the lamp from the radiator" is achieved due to the fact that the LED lamp contains a radiator, a printed circuit board, a light transmitting part and socles placed at both ends of the lamp. In this case, the printed circuit board is mounted on the radiator, and the surface of the radiator intended for mounting the printed circuit board is made flat and smooth. In this case, the radiator is made in the form of a thin-walled tube, while side cutouts are made at the ends of the flat part of the radiator.

Industrial applicability.

The authors of the group of inventions made a prototype LED lamp, tests of which confirmed the achievement of the technical result.

The inventive method of assembling an LED lamp and an LED lamp are implemented using industrially produced devices, can be applied at any electrical enterprise, and will find wide application in the electronics industry in the production of LED lamps.

INFORMATION SOURCES.

1. RF patent No. 84504 for utility model, IPC F21S 4/00, publ. 2009 year

Claims (25)

1. A method of assembling an LED lamp, including fixing a printed circuit board with mounted electronic components and electrical inputs on the radiator and installing a light transmitting part on the radiator, characterized in that side cutouts are preliminarily performed on the ends of the radiator, and after installing the light transmitting part on the radiator, both the sides of the lamp housing are installed socles, while the electrical inputs of the printed circuit board are partially inserted into the conclusions of the socles, then bring the socles to the end of the lamp and turn socles at a given angle. 2. The method according to claim 1, characterized in that the printed circuit board is mounted on the radiator using double-sided adhesive tape, the base of which is dielectric, and the thickness of the base is not more than 0.25 mm 3. The method according to claim 1, characterized in that the light-transmitting part is installed on the radiator by placing the sides of the light-transmitting part in the grooves of the radiator. 4. The method according to claim 1, characterized in that after the electrical inputs of the printed circuit board are partially inserted into the terminals of the sockets, the sockets are not brought to the end of the lamp all the way, and then the sockets are rotated through an angle of 90 °, at the same time bringing them to the end end of the lamp. 5. The method according to claim 1, characterized in that after installing the plinths, parts of the electrical inputs of the printed circuit board protruding beyond the terminals of the base are cut off. 6. The method according to claim 1, characterized in that after installing the sockets, the conclusions of the sockets are crimped. 7. LED lamp containing a radiator, a printed circuit board, a light transmitting part and socles located at both ends of the lamp, characterized in that the printed circuit board is mounted on the radiator, the surface of the radiator intended for mounting the printed circuit board is made flat and smooth, and at the ends radiator made side cutouts. 8. The lamp according to claim 7, characterized in that the radiator is made of aluminum. 9. The lamp according to claim 7, characterized in that the radiator is made in the form of a part of the cylinder formed by the section of the cylinder by a plane parallel to the axis of the cylinder. 10. The lamp according to claim 7, characterized in that the printed circuit board is made of PCB and mounted on the surface of the radiator with double-sided adhesive tape, the base of which is dielectric. 11. The lamp according to claim 7, characterized in that the light transmitting part is made in the form of a cylindrical groove, while the light transmitting part is made of plastic or glass. 12. The lamp according to claim 7, characterized in that the radiator is equipped with grooves, and the light transmitting part is provided with sides. 13. The lamp according to claim 7, characterized in that the ribs are made on the outer surface of the radiator. 14. The lamp according to claim 7, characterized in that the radiator contains cavities. 15. The lamp according to claim 7, characterized in that the circuit board is provided with two electrical inputs from each of the two ends, while the electrical inputs located on one end are made in the form of a single wire soldered to a platform on the printed circuit board near its middle. 16. The lamp according to claim 7, characterized in that from each of the two ends the printed circuit board is equipped with one electrical input, while the conclusions of the base are electrically connected to each other inside the base. 17. LED lamp containing a radiator, a printed circuit board, a light transmitting part and socles located at both ends of the lamp, characterized in that the printed circuit board is mounted on the radiator, the surface of the radiator intended for mounting the printed circuit board is made flat and smooth, while the radiator made in the form of a thin-walled tube, while side cutouts are made at the ends of the flat part of the radiator. 18. The lamp according to 17, characterized in that the cross section of the radiator is a segment of a circle. 19. The lamp according to 17, characterized in that the ribs are made on the cylindrical part of the outer surface of the radiator. 20. The lamp according to 17, characterized in that the side cutouts are made in the form of a semicircle. 21. The lamp according to 17, characterized in that the side cutouts are made in a rectangular shape. 22. The lamp according to claim 17, characterized in that the printed circuit board is made of textolite and is fixed on the surface of the radiator with double-sided adhesive tape, the base of which is dielectric. 23. The lamp according to claim 17, characterized in that each base is provided with two leads, and the leads are made primarily in the form of tubes fixed in a base housing on a dielectric holder. 24. The lamp according to claim 17, characterized in that the circuit board is provided with two electrical inputs from each of the two ends, while the electrical inputs located on one end are made in the form of a single wire soldered to a platform on the printed circuit board near its middle. 25. The lamp according to item 23, wherein the printed circuit board is equipped with one electrical input from each of the two ends, while the conclusions of the base are electrically connected to each other inside the base.

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