WO2016085364A1 - Linear light-emitting diode light source (variants) - Google Patents

Abstract

The invention relates to the field of producing light sources. A linear light-emitting diode light source comprises a tubular body which is see-through or transparent on the surface section opposite the light-emitting diode radiation elements, a metallic radiator is arranged along the tube and a board with a series of light-emitting diode radiation elements is secured on said radiator. The housing has contacts which can be connected to an externally disposable power unit for the series of light-emitting diode radiation elements. The tubular body is formed from two parts which are interconnected along the length of the housing, one of which is arranged above the above-mentioned board opposite the light-emitting diode radiation elements and is see-through or transparent, while the other is arranged on the reverse side of the above-mentioned board and is metallic in order to perform the function of removing heat from the housing cavity.

Description

 Linear LED light source (options)

 Technical field

 The invention relates to a new type of light source designed to replace fluorescent and fluorescent lamps and made on the basis of LEDs with the ability to insert into existing fixtures for fluorescent lamps or for stand-alone use in their own fixtures. Lamps with such lamps can be used in schools, hospitals, office buildings, have a high service life, ultrahigh consumption efficiency and complete environmental safety, do not require special disposal.

 State of the art

 Currently, LED tubes and LED lines have replaced neon and fluorescent lamps. This allowed us to significantly expand the range and characteristics of LED equipment for home lighting, architectural decorative lighting, advertising structures and lighting for retail and office space. A LED tube is a light source, that is, a lamp made in the form and size of a standard fluorescent tube (the so-called fluorescent lamp), containing a power supply and an LED board inside. Structurally, the LED tube is a polycarbonate tube with a diameter of up to 3 cm and a length of up to 2 meters. Light sources are installed in each tube - several dozens, or even hundreds of SMD LEDs of medium and low power. At the ends of the tube there are leads for connecting to a 220V AC power supply or a DC power source with a fixed output voltage.

LED tubes have many advantages: long LED life - up to ten years, high brightness, low power consumption, no harmful components, electrical safety, light without ultraviolet and infrared components, no flicker and delay when turned on, work without starters, ballasts and electronic ballasts. Especially it is necessary to dwell on the reliability and safety of LED tubes: some of them have the necessary protection class for working in outdoor conditions, and for power they do not need large mains voltages - 220V, enough 12 V. In addition, they have great mechanical and impact strength .

 A LED lamp for fluorescent luminaires (RU 104277) is known from RU 104277, comprising an electric board equipped with light emitting diodes located on it and connected in a working position to a power source.

 To keep the LED lamp in the working position, there are means for fixing and holding it. According to the overall dimensions of the fluorescent lamp, LED boards are installed, interconnected in a serial electrical circuit. The number of LED boards is determined from the condition that the LED lamp provides the level of illumination achieved by using a replaceable set of fluorescent lamps. The LED lamp includes a varistor and a zener diode, and additionally contains electronic devices for controlling light - these elements complicate the design of the lamp.

 Energy-saving LED tube lamps are also known for lighting public institutions and residential premises (LED lamps and lamps: http: //www.capita.rul 87). Such tubes are suitable for any standard fluorescent lamps (LVO, LPO).

 The known tube contains a radiator, on which the LED module is placed in the form of a board with an LED, which is built into the tube and is powered by an AC voltage of 220V. The board has pin contacts for inclusion in the electrical circuit of the lamp.

However, in this embodiment, in order to replace the luminescent light source in the luminaire with an LED light source, it is necessary to make the necessary structural changes in the wiring of the luminaire. Externally, connecting a fluorescent lamp is no different from connecting LED lamps. More precisely, it’s not even a connection, but the installation process itself - the fluorescent lamp was removed, the LED lamp was inserted. The problem is that LED tubes do not require ballasts (ballasts) to operate, or, more simply, they must be directly connected to the 220 V power supply, like a normal light bulb, while the power supply of fluorescent lamps at the time of starting requires a starter and a throttle (ballast, electronic ballast). Therefore, in the luminaire itself, in which the LED lamps will be installed, the switching circuit of the fluorescent lamp must be changed, i.e. it is necessary to remount the wires from the mains directly to the cartridges into which the base is inserted, bypassing the ballasts (starter and throttle). To install an LED tube instead of a fluorescent lamp, the following work must be done:

 - disconnect the wires from the starter;

 - disconnect the wires from the inductor;

 - connect the wires from the mains to the cartridge, i.e. apply a voltage of 220 V to the lamp directly.

 At the same time, dismantle the existing fittings, leaving only the body and the output to 220V. If you do not perform the above work, the LED lamp will work at high power and will quickly fail, which reduces the reliability of the LED lamp.

A linear LED light source is known, comprising a transparent tube with a radiator installed along the tube, on which a board with an LED circuit is mounted, which has pin contacts in the form of two conductive plugs for inclusion in the lamp circuitry, and the board is equipped with a circuitry containing a rectifier diode at the input a bridge connected in parallel with a stabilizing capacitor, which is connected in series to an LED circuit and a resistor balancing current ripple (RU1133 29, F21K2 / 00, H05B37 / 02 publ. 02/10/2012). This decision was made as a prototype for the declared objects. In the well-known LED lamp for fluorescent lamps, the board has pin contacts in the form of two conductive plugs for inclusion in the electrical circuit of the lamp and is equipped with an electrical circuit containing an input connector and a rectifier diode bridge connected in parallel with a stabilizing capacitor C1, which is connected in series to the LED circuit and the equalizing resistor Rl .Co of the throttle body integrated in the armature of the reactor through the connector, a current of 0.4A is supplied to the input of the diode bridge, which is rectified, pass I've been through a diode bridge and a capacitor C2 is stabilized. A stabilized current is passed through a resistor R1 to reduce its ripple; ultimately, a constant current is supplied to the LEDs, which ensures high-quality and reliable operation of the LEDs, which allows for maximum light output, reliability and durability of LED lamps.

 The disadvantage of this solution is that an uninsulated power supply with controls is built into a transparent tube. With this design, the potential of the mains supply may be present on the metal casing of the tube, which is dangerous in operation. When using an isolated PSU power supply (an isolated PSU is a power supply in which the secondary circuits are electrically isolated from the primary circuits by either capacitive or inductive coupling, inductive isolation in the form of a transformer is preferable), a transformer is required that does not fit in the compartment allocated to the power supply. In addition, even if the power supply was isolated, it would require a separate grounding of the tube body, and no one will ever do this.

The tubular LED light source is a product with a diameter of approximately 26 mm and with a sufficiently large length. Therefore, the placement of the PSU inside the tube requires miniaturization (rise in price) of the PSU components, it does not allow the use of an isolated power supply circuit. An insulated power supply unit requires grounding of the tube body, uninsulated - poses a danger of electric shock. Placing the PSU inside the tube limits the power of the tube. BP located inside the tube, additionally heats the LEDs on the section of the LED board, which is located above the power supply unit or next to the power supply unit. In addition, the LED board is fixed in the tube body with either glue or not fixed at all. Hence the instability of the contact spot of the LED board and the tube body (which serves as a heat sink), hence the poor heat transfer from the LEDs to the radiator (body), hence the reduced LED life. The volume of the tube body is occupied by the power supply. It is impossible to increase the surface area of the casing, since in this case the cooling fins will go beyond the dimensions of a standard fluorescent tube, and the LED tube will cease to be a universal replacement for a fluorescent tube. The LED has a too wide radiation pattern, as a rule - 150 °. In the cases of standard fixtures, a lot of light (up to 25%) will be lost due to the fact that the light will go out through the reflector, and not directly. And in some cases, in flat glass fixtures, this part of the light will simply be lost. Due to the presence of a PSU compartment inside the tube body, there is no room for any efficient optical system. A large number of fixtures in the world are made for more modern tubes with improved parameters, the so-called tubes T4 and T5, 12 and 16 millimeters in diameter, respectively. In such dimensions, a standard LED tube with a power supply inside does not fit.

 Disclosure of invention

 The present invention is aimed at achieving a technical result, which is to increase the service life by eliminating additional heating of the LED board, while increasing the light power by providing the same operating conditions for all LEDs at ambient temperature.

The specified technical result is achieved by the fact that in a linear LED light source containing a tubular housing made transparent or transparent on a surface portion opposite solid-state LED radiation elements, a metal radiator is placed along the tube on which a circuit board with a chain is fixed solid-state LED radiation elements, while the housing is made with electrical contacts, the tubular housing is made of two parts connected along the length of the housing, one of which is located above the indicated board opposite the solid-state LED radiation elements and is transparent or transparent, and the other is located on the back side the specified board and made of metal to implement the function of heat removal from the cavity of the housing, while these contacts on the housing are made with union with the external power supply chain disposable LED light elements.

 The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which the board is fixed with a coupler of solid-state LED radiation elements, while the housing is made with electrical contacts, the tubular casing is made of two parts connected along the length of the casing, one of which is located it is made above the specified board opposite the solid-state LED radiation elements and is made transparent or transparent, and the other is located on the reverse side of the specified board and is designed to implement the function of heat removal from the cavity of the metal casing with an inside area that is a radiator for the specified board having located along this board fasteners for clamping the board to the surface of the site.

The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements is fixed, while the housing completed with electrical contacts made with the possibility of connecting with an externally placed power supply unit of a chain of solid-state LED radiation elements, the tubular housing is made of two parts connected along the length of the housing, one of which is located above the specified board opposite the LED radiation elements and made transparent or transparent, and the other is located on the reverse side of the specified board and made of metal to implement the function of heat removal from the cavity of the housing, while I transparantnoy or transparent portion of the housing is made of plastic or mineral glass.

 The specified technical result is achieved by the fact that in a linear LED light source containing a tubular housing made of plastic or mineral glass, made on the surface opposite the solid-state LED radiation elements transparent or transparent, a metal radiator is placed along the tube, on which a board with a chain of solid-state LED radiation elements, while the housing is made with electrical contacts made with the possibility of connection with an external circuit board with a chain of solid-state LED radiation elements, opposite which the surface of the tubular body is made transparent or transparent, or the specified board with a chain of solid-state LED radiation elements is made elongated and part of it is bent and placed on the back of a metal radiator, opposite which the surface of the tubular Pusa is transparent or transparantnoy.

The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body, made on the surface opposite the solid-state LED radiation elements transparent or transparent, placed along the tube a metal radiator on which a board is fixed with a chain of solid-state LED radiation elements, the case being made with electrical contacts configured to connect an externally placed power supply unit of a chain of solid-state LED radiation elements, the tubular body is made of two parts connected along the length of the housing, one of which is located above the specified board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the reverse side of this board, it is made metal to carry out the function of heat removal from the cavity of the case, while guides are made in the device case for placing linear plates in them having optical properties for redirecting and / or mixing the rays incident from solid-state light sources and forming image of the desired radiation pattern of the light source.

The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements is fixed, while the housing made with electrical contacts made with the possibility of connection with an externally disposable power supply unit of the solid-state circuit of emitting diode radiation elements, the tubular casing is made of two parts connected along the length of the casing between each other, one of which is located above the indicated board opposite the LED radiation elements and made transparent or transparent, and the other is located on the back of the specified board and is made of metal to implement the heat removal function from the cavity of the case, while a transparent or transparent element of the case is made with a micro-prism system on its inner surface facing the PCB surface for ming light radiation pattern, or micro-prism system on its outer facing side of the surface board to form the desired radiation pattern of the light source.

 The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements is fixed, while the housing made with electrical contacts made with the possibility of connection with an externally disposable power supply unit of the solid-state circuit of emitting diode radiation elements, the tubular casing is made of two parts connected along the length of the casing between each other, one of which is located above the indicated board opposite the LED radiation elements and made transparent or transparent, and the other is located on the back of the specified board and is made of metal to implement the heat removal function from the cavity of the housing, while a transparent or transparent element of the housing is made with partial overlap by the diffuser to obtain a uniform light flux and and exclusions of the visibility of individual light points from solid-state LED radiation elements.

The specified technical result is achieved by the fact that in a linear LED light source containing a tubular body made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements is fixed, while the housing made with electrical contacts made with the possibility of connection with an externally disposable power supply unit of the solid-state circuit of emitting diode radiation elements, the tubular housing is made of two parts connected along the length of the housing between each other, one of which is located above the indicated board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the back side the specified board and is made of metal to implement the function of heat removal from the cavity of the case, while the transparent or transparent element of the case is filled with micro-granules, which provide the necessary degree of diffusion of light passing through the element to obtain a uniform light flux and exclude the visibility of individual light points from solid-state LED radiation elements.

 For the listed variants of execution, additions of the following type are possible.

 The circuit board with a chain of LED radiation elements is mounted on a transversely located platform, which is a radiator and which is made integral with the part of the housing that performs the function of heat removal from the housing cavity.

 The metal part for the implementation of the function of heat removal from the cavity of the body can be made with an externally located fins, and the electrical contacts are made in the form of a separate unit, which can rotate relative to the metal part of the body.

 The board mounting elements on the site are made integral with the platform for their mechanical bending or compression to press the board to the surface of the platform and ensure constant thermal contact of the board with the lower part of the case.

 These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

 Description of the figures of the drawings

The present invention is illustrated by specific examples of execution, which, however, are not the only possible, but clearly demonstrate the ability to achieve the desired technical result. In FIG. 1 shows a general view of a linear LED light source;

 FIG. 2 is a connection diagram of a linear LED light source with an external isolated power supply;

 FIG. 3 shows the first embodiment of a linear LED light source, fasteners for pressing the board to the surface of the site are in the initial position;

 FIG. 4 is the same as in FIG. I, the fastening elements are mechanically crimped to clamp the board to the surface of the site;

 FIG. 5 - shows a second embodiment of a linear LED light source

 FIG. 6 - shows a third embodiment of a linear LED light source;

 FIG. 7 - shows a fourth embodiment of a linear LED light source;

 FIG. 8 shows a fifth embodiment of a linear LED light source.

 The best embodiments of the invention

According to the present invention, the construction of a new tubular LED light source is considered (FIG. 1). This light source contains a tubular (tubular shape) housing made on a surface portion 1 opposite to the solid-state LED radiation elements 2 transparent or transparent. The housing is made with electrical contacts made with the possibility of connecting with an externally placed insulated power supply unit 3 (PSU) of a chain of LED radiation elements (Fig. 2). An isolated PSU is a power supply unit in which the secondary circuits are electrically isolated from the primary ones by either capacitive or inductive coupling . Inductive isolation in the form of a transformer is preferred. Electrical contacts can be made as a separate node that can rotate relative to the metal part of the body.

 In the general case, a tubular LED light source is considered, which comprises a tubular body made transparent or transparent on the surface of the surface opposite the solid-state LED radiation elements and inside which a metal radiator 4 is placed along the tube, on which a board 5 with a chain of solid-state LED radiation elements 2 is mounted. The housing is made with electrical contacts for connection with an externally placed insulated power supply unit of a chain of LED radiation elements. The tubular casing is made of two parts 5 and 6 connected along the length of the casing, one of which is located above the specified board opposite the solid-state LED radiation elements and is transparent or transparent, and the other is located on the back of the specified board and is made of metal to implement the heat removal function from the body cavity.

 In this case, the metal part of the case is made with an inside located platform, which is a radiator 4 for the specified board 5 and which has fastening elements 7 (clips or clamps) located along this board for clamping the board to the surface of the site. And the transparent or transparent part of the case is made of plastic or mineral glass.

The case itself is made in a tubular form, at the end of which a unit carrying electrical contacts is mounted in the form of a socle. This assembly may be stationary and rigidly connected to the housing. In this case, the light source will be an elongated lamp. Such plinths may be mounted at each end of the tubular body. If the node with electrical contacts is made at each end of the tube, then the lamp can be made similar in size and by connecting to a standard fluorescent tube (the so-called fluorescent lamp). If the node with electrical contacts is made rotary, then there is the ability to adjust the position of the transparent part of the surface of the housing in relation to the direction of lighting.

 Along the tube there is a metal radiator 4 on which a board 5 is fixed with a chain of solid-state LED radiation elements 2. The radiator is located transversely (in cross section) along the length of the housing and divides the internal cavity of the housing into two sections (Fig. 3). Thus, in the claimed tube-shaped light source, a part of the case located opposite the board is made to direct light radiation into the environment, and a part of the case located under the radiator, that is, on the back side of the board, is hollow, since the isolated PSU is removed from the case out and connected to the board through the electrical contacts of the node wires.

 Removing the PSU from the cavity of the case and placing it outside the case as a separate unit carrying a circuit for converting the initial voltage 220V of the centralized power supply network to direct current for supplying the TSI allows eliminating the high cost of the PSU (miniaturization of PSU components is not required), increasing the safety of the lamp electrical system in general, through the use of an isolated PSU, to increase the power of the light source to any desired level, without loss of quality PSU, and with an increase of 2-3 times the service life of TSI and PSU for Thu exception of heating TSI BP and BP by TSI.

As a rule, in known tubular light sources of LED type, the LED board is fixed in the tube body either with glue or not fixed at all. Hence the instability of the contact spot of the LED board and the tube body (which serves as a heat sink), hence the poor heat transfer from the LEDs to the radiator (body), hence the reduced LED life. To eliminate this drawback, it is proposed that the LED board must be mechanically mounted on the radiator. This ensures contact between the LED board and the radiator (case). It is proposed to carry out a radiator with fastening elements 6 located along this board for clamping the board to the surface of the site (Figs. 3 and 4). On the radiator are made clamps between which there is a board with solid-state light sources fixed to it. The board is fixed by mechanical bending or crimping of the clamps (Fig. 4), which allows for constant thermal contact of the board of solid-state light sources and the body radiator. The board mounting elements on the platform can be made integral with the platform for their mechanical bending or compression to press the board to the surface of the platform and ensure constant thermal contact of the board with the lower part of the case.

 The tubular casing is made of two parts connected along the length of the casing, one of which is located above the indicated board opposite the solid-state LED radiation elements and is made transparent or transparent, and the other part is located on the back of the specified board and is made of metal. The execution of the second part of the metal housing allows you to implement the function of heat removal from the cavity of the housing. To enhance heat dissipation, a part of the casing made of metal to realize the function of heat removal from the cavity of the casing can be made with an externally located fin 8 (Figs. 3, 5, and 6).

In this embodiment, the radiator can be made in the form of a platform connecting the end parts of the lower part of the housing, as shown in FIG. 4 and 5. A circuit board with a chain of LED radiation elements is mounted on a transversely located platform, which is a radiator and which is made integral with a part of the housing that performs the function of heat removal from the cavity of the housing. Thus, the entire lower part of the case is a radiator for the board, which greatly increases the heat sink and, as a result, increases the life of the light source by at least 2 times. Since lamps of the type of fluorescent tube (the so-called fluorescent lamp) are required to preserve the transverse dimensions, equipping standard LED tubes with finning would go beyond the dimensions of a standard fluorescent tube, and the LED tube would cease to be a universal replacement for this standard fluorescent tube. The exception of the BP placement inside the tube allowed changing the shape of the lower part of the casing by pressing it inward, but it is possible to place the developed cooling fins in the released space, as shown in FIG. 6. For other cases shown in FIG. 3 and 4, the ribs can be made on the outer surface of the lower part of the housing by organizing notches 9 that do not extend beyond the contour of the outer wall of the housing. The lower part of the housing may not have fins, but be designed to be developed, as shown in FIG. 5, in the direction of increasing the outer surface area of the lower part and limiting the area of a transparent or transparent portion of the upper part of the body.

 The LED has a too wide radiation pattern, as a rule - 150 °. In the cases of standard fixtures, a lot of light (up to 25%) will be lost due to the fact that the light will go out through the reflector, and not directly. And in some cases, in flat glass fixtures, this part of the light will simply be lost. Due to the presence of a compartment for the power supply unit (PSU) inside the tube body, there is no room for any efficient optical system. With the exception of placing the PSU in the case, the volume of the case is freed up, which allows you to make an optical system for LEDs and narrow the radiation pattern to the required 90 ° or another desired value, without increasing the dimensions of the tube above the permissible ones.

Such an example is shown in FIG. 5 and 6. An increase in the development of the area of the lower metal part of the casing made it possible not only to provide efficient heat dissipation, but also to use the walls 10 of this part of the casing for mounting linear plates 11 with optical properties for redirection and / or mixing in the guides on these walls (inside the casing) light rays incident from solid-state light sources. The transparent or transparent part of the housing in the proposed tubular light source is made of plastic (for example, polycarbonate) or glass.

 Below are examples of the performance of glass, which can greatly increase the light output of a lamp.

 The glass can be made with a microprism system on its inner surface facing toward the board to form a light pattern or with a microprism system on its outer surface away from the board to form a light pattern. Glass can be made with partial overlapping by the diffuser to obtain a uniform light flux and to exclude the visibility of individual light points from solid-state LED radiation elements. Or the glass is filled with microgranules that provide the necessary degree of diffusion of light passing through the glass to obtain a uniform light flux and exclude the visibility of individual light points from solid-state LED radiation elements.

 In FIG. 7 and 8 show an embodiment of a tubular LED light source that includes a tubular housing made of plastic or mineral glass. The housing can be made whole or in two parts. As in the previous examples, a metal radiator 4 is placed inside the case along the tube, on which a board 5 with a chain of solid-state LED radiation elements 2 is fixed on its front side, and opposite to this board the case or its part is made transparent or transparent.

A feature of this embodiment is that on the back of the metal radiator 4 there is an additional board 12 with a chain of solid individual LED radiation elements 2, opposite which the surface of the tubular body is made transparent or transparent. Alternatively, the specified board with a chain of solid-state LED radiation elements can be made elongated: part of it is located on the front surface of the radiator, and the other part is bent and placed on the back of the metal radiator, opposite which the surface of the tubular body is made transparent or transparent.

 As in the previously discussed examples, the board is mounted in clamps. The radiator itself may have developed side walls (see Fig. 8), which operate as cooling fins. These developed side walls can be used to place linear plates in guides or clamps that have optical properties for redirecting and / or mixing the rays incident from solid-state light sources.

 This utility model is industrially applicable and can be manufactured using technologies used in the manufacture of LED lamps. The utility model allows to increase the service life of a tubular LED light source by eliminating additional heating of the LED board while increasing the light power by providing the same operating conditions for all LEDs according to their ambient temperature inside the housing. At the same time, due to the introduction of a developed cooling radiator over the area of the radiator, it becomes possible to organize an optical directional system to bring the light beam into a fixed angle of 90 ° or another required angle.

Claims

Claim

 1. A linear LED light source comprising a tubular body made transparent or transparent on a surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, while the housing is made with electrical contacts, characterized in that the tubular housing is made of two parts connected along the length of the housing between each other, one of which is located above the specified circuit board A solid-state LED emitting element is transparent or transparent, and the other is located on the reverse side of the specified board and is made of metal to implement the function of heat removal from the cavity of the housing, while these contacts on the housing are made with the possibility of connecting with an externally placed insulated power supply unit of the LED element chain radiation.

 2. A tubular LED light source according to claim 1, characterized in that the board with a chain of LED radiation elements is mounted on a transversely located platform, which is a radiator and which is integral with a part of the casing that performs the function of heat removal from the cavity of the casing.

 3. The linear LED light source according to claim 1, characterized in that the part of the housing, made of metal for the implementation of the function of heat removal from the cavity of the housing, is made with an externally located fin.

 4. The linear LED light source according to claim 1, characterized in that the electrical contacts are made in the form of a separate unit, which can be rotated relative to the metal part of the housing.

5. A linear LED light source comprising a tubular housing made transparent or transparent on a surface portion opposite solid-state LED radiation elements; a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements, wherein the housing is made with electrical contacts, characterized in that the tubular housing is made of two parts connected along the length of the housing, one of which is located on the specified board opposite the solid-state LED radiation elements and is made transparent or transparent, and the other is located on the reverse side of the specified board and is designed to implement the function of heat removal from the cavity of the metal housing with an inside area, yayuscheysya radiator for said board having arranged along the board mounting elements for pressing the board to the pad surface.

 6. The linear LED light source according to claim 5, characterized in that said contacts on the housing are adapted to be connected to an externally disposed isolated power supply unit of a chain of solid-state LED radiation elements.

 7. The linear LED light source according to claim 5, characterized in that the part of the housing, made of metal for the implementation of the function of heat removal from the cavity of the housing, is made with an externally located fin.

 8. The linear LED light source according to claim 5, characterized in that the board mounting elements on the platform are made integral with the platform for mechanical bending or compression thereof to press the board against the surface of the board and ensure constant thermal contact of the board with the lower part of the case.

 9. The linear LED light source according to claim 5, characterized in that the electrical contacts are made in the form of a separate unit, which can be rotated relative to the metal part of the housing.

10. A linear LED light source comprising a tubular body made transparent or transparent on a surface opposite the solid-state LED radiation elements; a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, while the housing made with electrical contacts made with the possibility of connecting with an externally placed insulated power supply unit of a chain of solid-state LED radiation elements, characterized in that the tubular housing is made of two parts connected along the length of the housing, one of which is located above the board opposite the LED radiation elements and made transparent or transparent, and the other is located on the back of the specified board and is made of metal for the implementation of the function tap heat from the body cavity, wherein a transparent or made transparantnoy housing part made of plastic or glass.

 1 1. The linear LED light source according to claim 10, characterized in that the guides are arranged in the device body for placing linear plates in them having optical properties for redirecting and / or mixing the rays incident from solid-state light sources.

 12. The linear LED light source according to claim 10, characterized in that the glass is made with a microprism system on its inner surface facing the circuit board side to form a light pattern.

 13. The linear LED light source according to claim 10, characterized in that the glass is made with a microprism system on its external surface facing away from the board to form a light pattern.

 14. The linear LED light source according to claim 10, characterized in that the glass is partially overlapped by a diffuser to obtain a uniform light flux and to exclude the visibility of individual light points from solid-state LED radiation elements.

15. The linear LED light source according to claim 10, characterized in that the glass is filled with microgranules that provide the necessary degree of diffusion of light passing through the glass to obtain uniform light flux and eliminate visibility individual light points from solid-state LED radiation elements.

 16. The linear LED light source according to claim 10, characterized in that the electrical contacts are made in the form of a separate unit, which can be rotated relative to the metal part of the housing.

 17. A linear LED light source containing a tubular body made of plastic or mineral glass, made transparent or transparent on the surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a board with a chain of solid-state LED radiation elements is fixed, while the housing is made with electrical contacts made with the possibility of connection with an externally placed insulated power supply chain solid-state LED emitting elements, characterized in that on the back of the metal radiator there is an additional board with a chain of solid-state LED emitting elements, opposite which the surface of the tubular body is made transparent or transparent, or the specified board with a chain of solid-state LED emitting elements is elongated and its part is bent and placed on the back of a metal radiator, opposite which the surface of the tubular body is made pr transparent or transparent.

 18. The linear LED light source according to claim 17, characterized in that the housing is completely made transparent or transparent.

 19. The linear LED light source according to claim 17, characterized in that the guides are arranged in the housing of the device to accommodate linear plates having optical properties for redirecting and / or mixing the rays incident from solid-state light sources.

20. The linear LED light source according to claim 17, characterized in that the glass is made with a system of microprisms on its inner facing towards the surface plate to form a light pattern.

 21. The linear LED light source according to claim 17, characterized in that the glass is made with a microprism system on its external surface facing away from the board to form a light pattern.

 22. The linear LED light source according to claim 17, characterized in that the glass is partially overlapped by a diffuser to obtain a uniform light flux and to exclude the visibility of individual light points from solid-state LED radiation elements.

 23. The tubular LED light source according to claim 17, characterized in that the glass is filled with microgranules that provide the necessary degree of diffusion of light passing through the glass to obtain a uniform light flux and exclude the visibility of individual light points from solid-state LED radiation elements.

 24. The linear LED light source according to claim 17, characterized in that the electrical contacts are made in the form of a separate unit, which can be rotated relative to the housing.

25. A linear LED light source comprising a tubular housing made transparent or transparent on a surface opposite the solid-state LED radiation elements; a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, while the housing is made with electrical contacts made with the ability to connect with an externally placed power supply unit of a chain of solid-state LED radiation elements, characterized in that the tubular casing is made of two parts connected along the length of the casing, one of which is located above the specified board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the back side of the specified board and made metal for the implementation of the function of heat removal from the cavity of the housing, while in the housing there are guides for placing linear plates in them having optical properties for redirecting and / or mixing the rays incident from solid-state light sources and forming the desired radiation pattern of the light source.

 26. A linear LED light source comprising a tubular housing made transparent or transparent on a surface opposite the solid-state LED radiation elements; a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, while the housing is made with electrical contacts made with the ability to connect with an externally placed power supply unit of a chain of solid-state LED radiation elements, characterized in that the tubular casing is made of two parts connected along the length of the casing between each other, one of which is located above the specified board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the back side of the specified board and is made of metal to implement the function of heat dissipation from the body cavity, in this case, a transparent or transparent body element is made with a micro-prism system on its inner surface facing the board side to form a light diagram on directivity, or with a system of microprisms on its external surface away from the board to form the desired radiation pattern of the light source.

27. A linear LED light source comprising a tubular body made transparent or transparent on a surface opposite the solid-state LED radiation elements, a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, and the housing is made with electrical contacts made with the ability to connect to an externally placed power supply for the solid-state chain LED radiation elements, characterized in that the tubular housing is made of two parts connected along the length of the housing between each other, one of which is located above the indicated board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the back side of the specified board and is made of metal for the implementation of the function of heat removal from the cavity of the housing, while a transparent or transparent element of the housing is made with partial overlap by the diffuser to obtain uniform Oh luminous flux and eliminating the visibility of individual light points from solid-state LED radiation elements.

 28. A linear LED light source comprising a tubular body made transparent or transparent on a surface opposite the solid-state LED radiation elements; a metal radiator is placed along the tube on which a circuit board with a chain of solid-state LED radiation elements is fixed, while the body is made with electrical contacts made with the ability to connect with an externally placed power supply unit of a chain of solid-state LED radiation elements, characterized in that the tubular casing is made of two parts connected along the length of the casing between each other, one of which is located above the specified board opposite the LED radiation elements and is made transparent or transparent, and the other is located on the back side of the specified board and is made of metal to implement the function of heat dissipation from the body cavity, while a transparent or transparent element of the housing is filled with micro-granules, which provide the necessary degree of dispersion of light passing through the element for Acquiring uniform luminous flux exclusion and visibility of individual points of light emission from the solid state LED elements.