RU116202U1 - LED LAMP - Google Patents

Abstract

1. LED lamp, including a housing, the surface of which is made in the form of ribbing plates with a power supply installed inside and LED matrices with protective glass, while the housing is equipped with fastening docking elements for connecting to each other, made on the outer lateral sides of the housing,! characterized in that the open lower side of the luminaire body is provided with a protective glass attachment unit made in the form of undercuts on the inner surfaces of the body walls with the placement of the edges of the glass and the glass fixing element in them, while in the luminaire body there are at least two technological cavities with jumpers between them, connected with the side walls of the case, on the lower of which, made in the central part of the case parallel to the plane of the protective glass, with the help of at least one longitudinal T-shaped groove, LED matrices are fixed, and in the slots of the jumpers extending from the jumper with LED matrices, a bezel is fixed downward perpendicular to the plane of the protective glass. ! 2. A lamp according to claim 1, characterized in that the glass fixing element is made in the form of an elastic silicone or rubber cord. ! 3. The lamp according to claim 1, characterized in that an additional heat-absorbing, heat-insulating cavity is made between the technological cavity with the power supply located in it and the jumper with LED matrices. ! 4. The lamp according to claim 1, characterized in that the fastening element is made in the form of a horizontal bridge of the body pivotally connected to the end face through the side covers of the U-shaped bracket.

Description

The utility model relates to the field of lighting, in particular to lamps for lighting streets, roads, highways, squares, courtyards, for architectural lighting, etc.

A device is known - a street LED lamp, mounted on a support, comprising a housing with a light source installed inside the housing, and a power supply. (see RF patent for utility model No. 83587, F21S 13/10, 2009). The surface of the casing is made in the form of fins mounted on three sides around the perimeter of the casing, the light source is made in the form of an LED module in which light-emitting elements are combined in at least four parallel lines of serially connected heavy-duty LEDs, each LED is attached not only due to soldering of contact terminals, but also by soldering the heatsink heel of the LED to the special, electrically neutral contacts of the printed circuit board. In addition, the printed circuit board is made on a metal plate made of aluminum, rigidly fixed to the casing, to which copper foil is attached using pre-impregnated fiberglass fabric.

The disadvantages of the known LED luminaire include its low technological capabilities, which are the insufficient power of the used light emitting elements, and when using several lines of powerful LEDs to create the required luminous intensity of a street or indoor lamp of mass application, there is a possibility of overheating of the lamp due to insufficient heat removal on the housing from the plate with LEDs, which reduces the service life of the latter.

A known street LED lamp is a prototype (see RF patent for utility model No. 88769), mounted on a support, including at least one housing, the surface of which is made in the form of fins, an LED module installed inside the housing with LEDs connected in series between by itself on the printed circuit board, and the power supply, an optical light distribution lens is installed on top of each LED, the housing is equipped with fastening docking elements of the “dovetail” type, while in the housing the protective glass is fully installed.

The disadvantages of the prototype include its low technological and operational capabilities, consisting in the limited use of high-power LEDs and in a low-tech way of attaching a protective glass.

The objective of this utility model is to eliminate the disadvantages of the prototype while maintaining the necessary illumination parameters, in particular, expanding the technological capabilities of the device, increasing the degree of operational reliability, improving cooling conditions, simplifying the design, and universality used to obtain profile bodies.

The problem is achieved by combining the use of well-known features common with the prototype, including a housing, the surface of which is made in the form of fins with an internal power supply and LED matrices with protective glass, while the housing is equipped with fixing docking elements for connecting to each other, made on the outer side sides of the housing and new features characterized in that the open lower side of the lamp housing is equipped with a protective glass mount assembly made in the form of undercuts on the inner surfaces of the walls of the casing with the placement of the edges of the glass and the glass-fixing element in them, while at least two technological cavities are made in the lamp housing with jumpers between them connected with the side walls of the casing, on the lower of which, made LED matrices are fixed in the central part of the housing parallel to the protective glass plane using at least one longitudinal T-shaped groove, and in the grooves of the jumpers extending from the jumper with LED lights ritsami protective glass plane perpendicular down fixed bezel.

The glass fixing element is made in the form of an elastic silicone or rubber cord.

An additional heat-absorbing, heat-insulating cavity is made between the technological cavity with the power supply located in it and the jumper with LED arrays.

The fastening element is made in the form of a horizontal jumper of the housing pivotally connected to the end face through the side covers of the U-shaped bracket.

The novelty of the proposed device is the implementation on the open lower side of the lamp housing of the protective glass mount, made in the form of undercuts on the inner surfaces of the walls of the housing with the placement of the edges of the glass and the glass-fixing element, while at least two technological cavities are made in the lamp housing with jumpers between them, connected with the side walls of the housing, on the lower of which, made in the central part of the housing parallel to the plane of the protective glass with, at least one longitudinal T-shaped groove is mounted LED matrices, and in the grooves of the jumpers extending from the jumpers with LED matrices perpendicular to the plane of the protective glass down fixed panel.

So, the implementation of the attachment of the protective glass, made in the form of undercuts on the inner surfaces of the walls of the housing allows you to more tightly, reliably and hermetically fasten the glass without injuring it and providing a longer use, thereby increasing the manufacturability of its installation.

Mounting LED matrices directly on a jumper made in the central part of the housing parallel to the plane of the protective glass connected by jumpers to the finned housing of the lamp provides good heat dissipation.

The presence of a jumper in the central part of the body cavity with at least one longitudinal T-shaped groove in it allows expanding the technological capabilities of the luminaire associated with the possibility of installing matrices of various sizes and power in its cavity.

Signs of the implementation of the glass-fixing element in the form of an elastic silicone or rubber cord, the execution between the technological cavity with the power supply unit located in it and the jumper with LED matrices of an additional heat-absorbing, heat-insulating cavity and the fastening element being made in the form of a horizontal body jumper pivotally connected to the end face through the side covers П -shaped braces - are additional features aimed at revealing the design features of the main features on the achievement of the objectives of useful model.

According to the patent information search, the features of the proposed device are new, non-obvious, industrially feasible and aimed at achieving a positive result, which is the task of the proposed utility model.

Figure 1 schematically shows a General view of the proposed lamp in disassembled form.

Figure 2 shows the cross section of the lamp with the display of its structural elements.

Figure 3 shows the mounting options for the modules in the grooves of the jumper when viewed from below.

Figure 4 shows the mounting options for lamps of various designs.

The proposed lamp contains a finned body 1, on the open end of which on the inner surface of the side walls there are undercuts 2 for fixing the protective glass 3 using an elastic silicone or rubber cord 4. Inside the body 1, several additional cavities are made. A power supply unit 5 is mounted in the upper cavity. The middle cavity 6 is heat insulating and heat dissipating heat from the LED matrices 7, 8 preventing overheating of the power supply unit 5. On the lower jumper 9 with at least one T-shaped groove 10 are fastened with screws 19 and nuts 20, the LED arrays 7, 8. At the same time, the LED arrays of various sizes and power, having holes or slots, can be fixed on the underside of the jumper 9 as shown in FIG. 3. Moreover, the smaller matrix is installed along the axis of the slots perpendicular to the longitudinal plane of the lamp - the distance between its slots allows the matrix 7 to be fixed directly. The matrix 8 has large dimensions and large distances between the holes for its fastening. Therefore, it is installed at a certain angle ά to the longitudinal axis of the lamp. On the bridges 11 perpendicular to the protective glass 3 and extending from the bridging 9 with LED matrices, longitudinal grooves 12 are made in which a false panel 13 is installed. The dovetail connecting elements 14 are made on the outer side walls of the lamp housing 1. A longitudinal T-shaped groove 15 is made on the upper side of the housing for entering the fastening elements of the lamp onto the bracket, the surface of walls or ceilings, the mounting method is shown in Fig.4. The fastening elements can be made in the form of a bracket 16, pivotally with bolts 21 connected to the lateral sides of the jumper 9 of the housing 1 through the lids 17, 18 of the lamp into the threaded hole 22. The grooves 10 are made so that they can be fixed in different sizes and power matrix with the location of the screws 19 and nuts 20 either perpendicular (see figure 3) to the longitudinal axis of the lamp, or at an angle ά to it. So when installing, for example, a small matrix 7 cutouts which are installed perpendicular to the longitudinal axis. In this case, the nut 20 is installed in the groove 10 and with the help of screws 19, the matrix 7 is attached to the jumper 9. When installing matrices of large sizes and greater power 8, the latter are installed at a certain angle ά to the longitudinal axis of the lamp housing.

After installing the power supply unit 5 in the upper cavity of the luminaire and fixing the LED matrices 7.8 in the longitudinal grooves 12, a false panel 13 is installed that closes the fastening and soldering of the matrices, and a protective glass 3 is installed in the undercuts 2, which is tightly fastened in the undercuts 2 using rubber or an elastic silicone cord 4. The lamp has several mounting options: on a U-shaped bracket 16, on the headband of the mast with an arm 23, on supporting structures (ceilings, walls) using a T-shaped groove 15 - mounting options presented in figure 4.

The proposed lamp works as follows:

When applying AC voltage to the power supply 5, the voltage is converted from AC to DC with stabilized current. The LEDs of the matrices 7 or 8 begin to emit light, creating a luminous flux directed towards the illuminated surface. Heat from the LED matrices through the jumpers is transferred to the finned body 1 and is removed to the atmosphere. The presence of a heat-insulating middle cavity 6 in the housing 1 creates the effect of a "thermos" and limits this to heat from the LED matrix to the power supply 5. Using the bracket 16 allows you to fix the lamp as a spotlight, and due to its hinge connection with the housing to change the direction of the light flux, using T-slot 15 is mounted on a mast or supporting structure.

Currently, the proposed device has developed design documentation. Start production is expected in the first quarter of 2012.

Testing fixtures showed positive results.

Claims (4)

1. LED lamp, comprising a housing, the surface of which is made in the form of fins with an internal power supply and LED matrices with protective glass, while the housing is equipped with fastening docking elements for connecting to each other, made on the outer sides of the housing, characterized in that the open lower side of the luminaire housing is equipped with a protective glass mount assembly made in the form of undercuts on the inner surfaces of the housing walls with the edges of the glass and the glass fixing element placed in them, while at least two technological cavities with jumpers between them associated with the side walls of the housing, on the lower of which, made in the central part of the housing parallel to the plane of the protective glass, using at least one ol T-shaped slot secured LED matrix, and webs in the grooves extending from the webs with the LED array, the protective glass plane perpendicularly downward is fixed bezel. 2. The lamp according to claim 1, characterized in that the glass-fixing element is made in the form of an elastic silicone or rubber cord. 3. The lamp according to claim 1, characterized in that between the technological cavity with the power supply located in it and a jumper with LED arrays, an additional heat-absorbing, heat-insulating cavity is made. 4. The lamp according to claim 1, characterized in that the fastening element is made in the form of a horizontal body jumper pivotally connected to the end face through the side covers of the U-shaped bracket.