RU154281U1 - LED LAMP - Google Patents

Abstract

1. An LED lamp comprising a radiator housing, a printed circuit board made of heat-conducting material, on which the LEDs are placed, as well as a power supply unit with electrical wiring connected to the printed circuit board, and a protective shield in the form of a round multi-lens made of optically transparent material and fixed in the housing -radiator by means of a clamping ring, characterized in that it further comprises a knot for adjusting the focal length and precise positioning of the multi-lens, while this node is placed in the housing torus and consists of a removable substrate, made in the form of a circle of heat-conducting material, and centering sleeves having upper and lower parts, and in the removable substrate and on the printed circuit board placed on it, the central holes are made in which the power supply wiring is placed, and also coaxial mounting holes in which the upper part of the centering sleeves is installed, and on the round multi-lens there are corresponding mounting ledges in which the lower part of the centering sleeves is installed. 2. The LED lamp according to claim 1, characterized in that the change in the light intensity curve is controlled by changing the thickness of the replaceable substrate, while the thickness of the replaceable substrate is determined from the equation Y = -4.4x + 47.5x-68, where Y is the angle of illumination, x - thickness of the replaceable substrate. 3. The LED lamp according to claim 1 or 2, characterized in that the casing-radiator is made integral, comprising a massive heat sink base and a radiator attached to the base, while the massive heat sink base has a central hole in which the electrical wiring is located

Description

The utility model relates to lighting engineering, in particular, to designs of lighting devices based on light-emitting diodes, intended for lighting rooms with high ceilings of various industrial, warehouse, commercial and public buildings.

An analogue is an LED lamp, which contains a cast housing made of aluminum alloy, a power supply located inside the housing, a round-shaped printed circuit board with LEDs located on it, a primary optical system and a secondary circular optical system (multi-lens) with a diameter equal to the diameter of the printed circuit board, while the LEDs on the printed circuit board form several separate segments, and the secondary optical system contains multi-lens segments and is installed with possible awn radial movement relative to the lamp axis (patent RU №2509952 C2, IPC F21S 8/00, 20.03.14).

The main disadvantage of the analogue is its low performance due to the insufficiently high efficiency of heat removal from the printed circuit board with LEDs as a result of the possibility of dust and dirt particles on the housing of the LED lamp, as well as due to the fact that when the LEDs are segmented on the board, the efficiency decreases heat sink from the LEDs due to a decrease in the utilization of the area of the printed circuit board.

In addition, the optical-mechanical system used in the analogue has the following disadvantages:

1. The complexity of its design, since the secondary optics consists of 3 groups of lenses, each of which contains 3 segments of multi-lenses, providing no more than 3 light intensity curves (KSS).

2. The need to change the optical-mechanical system of the luminaire to provide a larger quantity than 3 KSS, with a larger, smaller, or intermediate value of the radiation angle with the required step.

3. The difficulty of ensuring high alignment of LED optics (round multi-lens) relative to LEDs.

The prototype is the PSS KOLOKOL industrial pendant LED luminaire containing a radiator case, a printed circuit board of heat-conducting material on which the LEDs are placed, as well as a power supply unit with electrical wiring located inside the case, and a protective screen in the form of a round multi-lens made of optically transparent material and fixed in the housing by means of a clamping ring (http://www.ledsvet.ru/promishlennie-svetodiodnie-svetilniki-pss-kolokol-povishennpy-moshnosti/).

The lamp, in which the radiator case is made in Hi-tech design, has a dual-circuit heat sink. The luminaire has a maximum power of 100 W, an optical system that provides narrow-degree concentrated light intensity curves.

The disadvantages of the prototype are the need to change the type of multi-lens when setting a new radiation angle and the need for a large set of multi-lenses to change its radiation angle, the low accuracy of the positioning of LED optics (round multi-lens) relative to the LEDs, as well as the relatively low range of the angle of illumination (23 ° -60 °) .

In addition, the disadvantage of the prototype is its low performance due to the insufficiently high efficiency of heat removal from the printed circuit board with LEDs, which reduces heat transfer to the environment, leads to an increase in the temperature of the LEDs and, as a result, to a decrease in the operational reliability of the luminaire luminaire service, due to the limitation in the number and power of LEDs used in the design of the luminaire (double-circuit heat sink, provides a maximum power equal to 100 W), as well as due to the possibility of overheating of the power supply with wiring, as it is located inside the case.

The objective of the utility model is the development of an LED lamp in which the indicated disadvantages of the prototype are eliminated.

The technical result is to increase operational characteristics by providing the required light intensity curve by changing the focal length of one circular multi-lens, ensuring high accuracy of positioning of LED optics (round multi-lens) relative to LEDs, expanding the range of the angle of illumination to 15 ° -60 °.

In addition, the technical result is an increase in performance by increasing the power of the luminaire to 180 W, eliminating overheating of the power supply with electrical wiring, increasing the efficiency of heat dissipation from a printed circuit board with LEDs by providing multi-circuit heat sink and creating the effect of a chimney.

The technical result is achieved by the fact that the LED lamp comprising a radiator housing, a printed circuit board made of heat-conducting material, on which the LEDs are placed, as well as a power supply unit with electrical wiring connected to the printed circuit board, and a protective screen in the form of a round multi-lens made of optically transparent material and fixed in the body-radiator by means of a clamping ring, according to the present utility model, further comprises a focal length adjustment and precise multi positioning unit insa, while the specified node is placed in the radiator case and consists of a removable substrate made in the form of a circle of heat-conducting material, and centering sleeves having upper and lower parts, the central ones being made in the removable substrate and on the printed circuit board placed on it holes in which the power supply wiring is located, as well as coaxial mounting holes in which the upper part of the centering sleeves is installed, and the corresponding mounting tabs are made on the round multi-lens, in which the installation to the bottom of the centering sleeves.

Changing the light intensity curve is adjusted by changing the removable substrate thickness, wherein the thickness of the removable substrate is determined from the equation Y = ² + -4,4h 47,5h-68, wherein Y - angle of illumination, x - the thickness of the removable substrate.

The radiator case is made integral, containing a massive heat sink base and a radiator attached to the base, while the massive heat sink base has a central hole in which the power supply wiring is located, and is made in the form of a truncated cone, the outer surface of which has fins, and the radiator is made in the form of the inner and outer cylinders with open upper and lower planes mounted coaxially and interconnected by means of longitudinal radial stiffeners, set flanged to the corresponding ribs of the massive heat sink base, the inner cylinder has a massive wall, the outer cylinder is made thin-walled with a flanked outer surface, a longitudinal open cavity is made between the inner and outer cylinders, in which the power unit is located, and the radiator has seats on the outer surface of the inner cylinder, made in the form of protrusions, which are longitudinal ribs on which the power supply is fixed, and the outer surface of the radiator is made an anodized surface or surfaces with a polymeric anti-dust coating.

When fixing the radiator to a massive heat sink, heat-conducting glue is used.

On the lower plane of the massive heat sink base, seats are made in which a multi-lens, o-ring, removable substrate with a printed circuit board, fasteners for fixing the massive heat sink base to the radiator are placed, and on the upper plane of the massive heat sink base, on which the lower plane of the inner cylinder with a massive wall, made a seat in which the insulator of the electrical wiring of the power supply.

The massive heat sink base on which the radiator is mounted is made of cast aluminum alloy, while the outer surface of the base is made in the form of an anodized surface or a surface with a polymer dust-repellent coating.

The power supply insulator is a heat-conducting silicone two-component compound.

A hole is made in the massive wall of the lower part of the inner cylinder of the radiator, in which a sealed gland of the power supply wiring is connected, connected to the insulator.

A flange is mounted on the massive wall of the upper plane of the inner cylinder of the radiator, on which the eye-bolt of the pendant fixture is placed.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows the proposed LED lamp (longitudinal section), in FIG. 2 shows the placement of the focal length adjustment and precise positioning multi-lens unit in a massive heat sink (local view B in FIG. 1), FIG. 3 - placement of the power supply in a radiator case (cross section A-A in FIG. 1), in FIG. 4 shows a multi-lens (view A in FIG. 1), and in FIG. 5 shows a printed circuit board with LEDs.

In the drawings, the numbers indicate:

1 - radiator

2 - massive heat sink base, made in the form of a truncated cone,

3 - replaceable substrate made in the form of a circle of heat-conducting material,

4 - printed circuit board made of heat-conducting material,

5 - LEDs

6 - round multi-lens,

7 - centering bushings having upper and lower parts,

8 - a sealing ring,

9 - fasteners for fastening a round multi-lens,

10 - clamping ring,

11 - power supply unit with wiring,

12 - eye bolt

13 - fasteners for mounting a massive heat sink base to the radiator,

14 - sealed seal

15 - insulator (thermally conductive silicone two-component compound),

16 - mounting holes in a removable substrate,

17 - mounting holes on the printed circuit board,

18 - mounting tabs on a round multi-lens, in which the lower part of the centering bushings is installed,

19 - ribs on a massive heat sink,

20 - the inner cylinder of the radiator having a massive wall,

21 - the outer cylinder of the radiator, made thin-walled with a flanked outer surface,

22 - longitudinal radial stiffeners connecting the inner and outer cylinders,

23 - seats made in the form of protrusions, which are longitudinal ribs on which the power supply is fixed,

24 is a longitudinal open cavity in which the power supply is located,

25 - seat in which the multi-lens is placed,

26 - a seat in which the o-ring is placed,

27 - a seat in which is placed a removable substrate with a printed circuit board,

28 - seats in which fasteners are placed securing the massive heat sink base to the radiator,

29 - the upper plane of the massive heat sink base, on which the lower plane of the inner cylinder is installed,

30 - the lower plane of the inner cylinder with a massive wall,

31 - seat in which the insulator of the electrical wiring of the power supply,

32 - a hole in which is sealed gland electrical wiring of the power supply,

33 - a flange on which the eye-bolt of the pendant fixture is placed,

34 - the Central holes in the base, removable substrate and the printed circuit board, which houses the wiring of the power supply.

The LED lamp (Fig. 1) contains a radiator case, a printed circuit board 4 made of heat-conducting material, on which the LEDs 5 are placed, as well as a power supply unit 11 with electrical wiring connected to the printed circuit board 4, and a protective screen in the form of a circular multi-lens 6 made of optically transparent material and fixed by fasteners 9 in the body-radiator using the clamping ring 10.

The LED lamp also contains, increasing its operational characteristics, a driver with galvanic isolation, which allows protecting the LEDs from burnout in case of failure of the power supply (not shown conventionally in the drawing).

The proposed LED lamp is characterized in that it additionally contains a node for adjusting the focal length and precise positioning of the multi-lens 6 (Fig. 2). The control unit of the focal length and precise positioning of the multi-lens 6 is placed in the radiator body and consists of a removable substrate 3 made in the form of a circle of heat-conducting material, and centering sleeves 7 having upper and lower parts.

In the removable substrate 3 and on the printed circuit board 4 placed on it, the central holes 34 are made in which the wiring of the power supply unit 11 is placed (in the drawing, the indicated arrangement is conventionally not shown).

In the interchangeable substrate 3 and on the printed circuit board 4 placed on it, coaxial mounting holes are made, respectively 16 and 17, in which the upper part of the centering sleeves 7 is installed, and on the round multi-lens 6 are made the corresponding mounting protrusions 18, in which the lower part of the centering bushings 7.

Changing the curve of intensity is adjusted by changing the thickness of the removable substrate 3, the thickness of the removable substrate 3 is determined from the equation Y = ² + -4,4h 47,5h-68, wherein Y - angle of illumination, x - the thickness of the removable substrate.

The radiator case is made integral, comprising a massive heat sink base 2 and a radiator 1 attached to the base 2 (Fig. 1). The massive heat sink base 2 has a central hole 34 in which the wiring of the power supply unit is located (in the drawing, this arrangement is conventionally not shown). Massive heat sink base 2 is made in the form of a truncated cone, the outer surface of which has ribs 19.

The radiator 1 is made in the form of an inner 20 and an outer 21 cylinders with open upper and lower planes mounted coaxially and interconnected using longitudinal radial stiffeners 22. Longitudinal radial stiffening ribs 22 are mounted on the corresponding ribs 19 of the massive heat sink 2. The inner cylinder 20 has a massive wall, and the outer cylinder 21 is thin-walled with a flanked outer surface (Fig. 3).

Between the inner 19 and the outer 20 cylinders a longitudinal open cavity 24 is made in which the power supply unit 11 is placed. The radiator 1 has on the outer surface of the inner cylinder 20 seats 23 made in the form of protrusions, which are longitudinal ribs on which the power supply unit 11 is fixed.

When fixing the radiator 1 on a massive heat sink 2 use heat-conducting adhesive.

On the lower plane of the massive heat sink base 2, seats 25, 26, 27, 28 are made in which, respectively, a multi-lens 6, an o-ring 8, a removable substrate 3 with a printed circuit board 4, fasteners 13 for fixing the massive heat sink base 2 to the radiator 1 are placed.

On the upper plane 29 of the massive heat sink base 2, on which the lower plane 30 of the inner cylinder with a massive wall is mounted, a seat 31 is made in which the insulator 15 of the wiring of the power supply unit 11 is placed (Fig. 1).

The massive heat sink 2, on which the radiator 1 is mounted, is made of cast aluminum alloy.

The insulator 15 of the electrical wiring of the power supply unit 11, which provides watertightness and security of the electrical connection of the power supply unit 11, is a heat-conducting silicone two-component compound.

An opening 32 is made in the massive wall of the lower part of the inner cylinder 20 of the radiator 1, in which a sealed gland 14 of the electrical wiring of the power supply unit 11 is connected, connected to the insulator 15.

A flange 33 is mounted on the massive wall of the upper plane of the inner cylinder 20 of the radiator, on which the eyebolt 12 of the pendant lamp is mounted.

LED lamp works as follows.

When the LED lamp is connected to the mains supply through the power supply unit 11, a constant stabilized current is supplied to the LEDs 5, providing their luminescence, while the heat is released, which is dissipated by the radiator 1 and the massive heat sink base 2. In this case, the heat sink efficiency is increased due to the multi-loop effect heat dissipation. The initial heat removal from the LEDs 5 is carried out by the printed circuit board 4, and the removable substrate 3, a massive heat sink base 2, an inner cylinder 20 having a massive wall, longitudinal radial ribs 22 stiffness, the side surface of the outer cylinder 21 with longitudinal ribs 23 produce multi-loop heat dissipation from printed circuit board 4 with LEDs 5. Fixing the radiator 1 on a massive heat sink 2 using heat-conducting glue also improves the heat sink. Such a multi-circuit heat sink prevents overheating of component parts, increases the reliability of the LED lamp and its long life, provides fire safety, and in addition, allows the use of a large number of LEDs and the use of high power LEDs. To optimize the thermal mode of operation of the power supply unit 11 of the LED lamp, it is placed in a longitudinal open cavity 24 and fixed on the protrusions (seats 23), which exclude thermal contact with the radiator 1 and ensure optimal cooling of the power supply unit 11, and, consequently, increase its service life.

The implementation of the outer surface of the radiator 1 and the base 2 in the form of an anodized surface or a surface with a polymer dust-repellent coating does not allow dust to accumulate and also provides stable heat dissipation from the printed circuit board 4 with LEDs 5 and the power supply unit 11.

The proposed LED lamp has improved thermal characteristics also by increasing the efficiency of convective heat transfer.

Since the radiator 1 is made in the form of an inner 20 and an outer 21 cylinders with open upper and lower planes, mounted coaxially and interconnected by longitudinal radial stiffeners 22, the cavities between the longitudinal radial stiffeners 22 of the radiator 1 form channels for air flow, which arises as a result of a difference in temperatures and, accordingly, pressures on the lower and upper planes of the outer cylinder 21, due to which air draft is generated and the effect of an exhaust pipe is created, which ensures AET effective natural convective heat transfer.

In addition, the air flow, blowing the outer side surface of the radiator 1 and the surface of the power supply 11, prevents the accumulation of dust and dirt on them, which also provides improved thermal performance.

Thus, the design of the proposed LED lamp allows for efficient heat dissipation from the printed circuit board 4 with LEDs 5 and the power supply 11, while the mass of the lamp does not exceed 7 kg at a power consumption of 180 watts.

The temperature of the LED lamp at a power consumption of 180 W and an ambient temperature of 25 ° C does not exceed 45 ° C.

The absence of overheating of the LEDs prevents the degradation of crystals, thereby ensuring a long life of the LED lamp (lamp life of at least 100 thousand hours) without significantly reducing the light flux.

When changing the suspension height of the LED lamp, it is necessary to change the axial illumination of the working surface in accordance with its required level, using LED lamps with different angles of illumination. The presence in the proposed LED lamp controlling unit focal length and precise positioning of the multi-6 allows to change the light intensity curve adjusted by changing the thickness of the removable substrate 3, the thickness of the removable substrate 3 is determined from the equation Y = ² + -4,4h 47,5h-68 where Y is the angle of illumination, x is the thickness of the removable substrate. For example, for luminescence angles equal to 15 °, 40 °, 60 °, the thickness of the replaceable substrate should be equal to 2 mm, 4 mm, 5 mm, respectively. The precise positioning of the multi-lens 6 due to the presence of centering sleeves 7 having upper and lower parts, provides high alignment of LED optics with respect to LEDs.

Using the proposed utility model, in comparison with the analogue and prototype, will improve the operational characteristics of the LED lamp by providing the required light intensity curve by changing the focal length of one circular multi-lens, ensuring high accuracy of positioning of the LED optics (round multi-lens) relative to the LEDs, expanding the range of the angle of illumination up to 15 ° -60 °, increasing the power of the lamp up to 180 W, eliminating overheating of the power supply with electrical wiring by p placement not inside the radiator, but in its longitudinal open cavity, and fixing on the protrusions that exclude thermal contact with the radiator, as well as by increasing the efficiency of heat dissipation from the printed circuit board with LEDs by providing multi-circuit heat sink and creating the effect of the exhaust pipe.

Claims (9)

1. An LED lamp comprising a radiator housing, a printed circuit board made of heat-conducting material, on which the LEDs are placed, as well as a power supply unit with electrical wiring connected to the printed circuit board, and a protective shield in the form of a round multi-lens made of optically transparent material and fixed in the housing -radiator by means of a clamping ring, characterized in that it further comprises a knot for adjusting the focal length and precise positioning of the multi-lens, while this node is placed in the housing torus and consists of a removable substrate, made in the form of a circle of heat-conducting material, and centering sleeves having upper and lower parts, and in the removable substrate and on the printed circuit board placed on it, the central holes are made in which the power supply wiring is placed, and also coaxial mounting holes in which the upper part of the centering sleeves is mounted, and on the round multi-lens there are corresponding mounting ledges in which the lower part of the centering sleeves is mounted. 2. The LED lamp according to claim 1, characterized in that the variation of the light intensity curve is adjusted by changing the removable substrate thickness, wherein the thickness of the removable substrate is determined from the equation Y = ² + -4,4h 47,5h-68, wherein Y -. Angle glow, x is the thickness of the removable substrate. 3. The LED lamp according to claim 1 or 2, characterized in that the casing-radiator is made integral, containing a massive heat sink and a radiator attached to the base, while the massive heat sink has a central hole in which the power supply wiring is located, and is made in the form of a truncated cone, the outer surface of which has ribs, and the radiator is made in the form of inner and outer cylinders with open upper and lower planes mounted coaxially and connected to each other with the help of longitudinal radial stiffeners mounted on the corresponding ribs of the massive heat-dissipating base, the inner cylinder has a massive wall, the outer cylinder is made thin-walled with a flanked outer surface, a longitudinal open cavity is made between the inner and outer cylinders, in which the radiator has on the outer surface of the inner cylinder, seats made in the form of protrusions, which are longitudinal ribs, on which a bl to supply, wherein the outer surface of the radiator is made in the form of an anodized surface or surfaces with a polymeric anti-dust coating. 4. The LED lamp according to claim 1, 2, or 3, characterized in that when fixing the radiator to a massive heat sink base, heat-conducting adhesive is used. 5. The LED lamp according to claim 1, or 2, or 3, or 4, characterized in that on the lower plane of the massive heat sink base, seats are made in which the multi-lens, O-ring, interchangeable substrate with a printed circuit board, fasteners for securing the massive the heat sink base to the radiator body, and on the upper plane of the massive heat sink base, on which the lower plane of the inner cylinder with a massive wall is mounted, a seat is made in which the insulator is placed power supply wiring. 6. The LED lamp according to claim 1, or 2, or 3, or 4, or 5, characterized in that the massive heat sink on which the radiator is mounted is made of cast aluminum alloy, while the outer surface of the base is made in the form of an anodized surface or surfaces with a polymer dust-repellent coating. 7. The LED lamp according to claim 1, or 2, or 3, or 4, or 5, or 6, characterized in that the electrical wiring insulator of the power supply is a heat-conducting silicone two-component compound. 8. The LED lamp according to claim 1, or 2, or 3, or 4, or 5, 6, or 7, characterized in that a hole is made in the massive wall of the lower part of the inner cylinder of the radiator, in which a sealed gland of the power supply wiring is placed connected to the insulator. 9. The LED lamp according to claim 1, or 2, or 3, or 4, or 5, 6, or 7, or 8, characterized in that a flange is mounted on the massive wall of the upper plane of the inner cylinder of the radiator, on which the eye pendant lamp bolt.

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