RU152787U1 - LAMP - Google Patents

Abstract

1. A luminaire containing a base made of heat-conducting material, a ceiling having through holes for a fastener and connected to the base of the lamp, a diffuse diffuser, a printed circuit board located in the inner cavity of the lamp and connected to the base, LEDs with their power circuit located on the printed circuit board , a motion sensor and a light sensor mounted on a printed circuit board with the ability to control the power supply circuit of the LEDs, and a fastener, characterized in that the holes for the fastener made on the ceiling, on the printed circuit board and on the base of the lamp, so that they have a common vertical axis, the hole on the ceiling is placed in the central part of the recess made in the central part of the ceiling, the ceiling, the printed circuit board and the base are interconnected by means of a fastener, passing through the indicated holes and equipped with a countersunk head having a non-standard slot. 2. The luminaire according to claim 1, characterized in that the recess in the central part of the lampshade is made in the form of a truncated cone, the smaller base of which is facing the inner cavity of the lamp, and the larger base is outward, while the hole for the fastener is made in the central part of the smaller base. . The lamp according to claim 2, characterized in that the diameter of the larger base of the recess on the plafond in the shape of a truncated cone is not more than 1/3 of its height. 4. The lamp according to claim 1, characterized in that, on the basis of the lamp, grooves are additionally made in which a printed circuit board is movably mounted. The lamp according to claim 1, characterized in that it is additionally equipped

Description

Lamp

This utility model relates to the field of lighting, namely to lighting devices intended for fixed installation, and can find application in the manufacture of lamps used both for lighting indoor and outdoor lighting.

Known lamp designed to illuminate the interior of various purposes (RF Patent No. 108117 "LED network light for general use", IPC F 21S 8/00, from 12.27.2010, publ. 09/10/2011). The luminaire is a printed circuit board with a metal base on which the LEDs are installed, and a means of connecting to the electrical network.

A disadvantage of the known device design is the low reliability due to the high probability of failure due to the possibility of free access by unauthorized persons to the LEDs and the printed circuit board.

Known lamp used primarily for lighting enclosed spaces (RF Patent No. 98529 "Lamp", IPC F 21S 4/00, from 05.21.2010, publ. 20.10.2010). This lamp contains a ceiling and a printed circuit board with LEDs mounted inside the ceiling. The ceiling has openings for natural ventilation and, at least on both sides, openings for fasteners for installing the lamp on a supporting surface (wall, ceiling). The luminaire is equipped with a motion sensor with the ability to control the power supply circuit of the LEDs and an ambient light sensor with the ability to control a motion sensor.

The disadvantage of this analogue is the relatively low reliability of operation, due to the possibility of free access by unauthorized persons to the fastener elements and, as a result, its unauthorized dismantling and failure.

The closest in technical essence to the claimed utility model is a lamp designed to illuminate the infrastructure of housing and communal services (RF Patent No. 91136 "Housing and communal services lamp", IPC F 21S 4/00, dated 07.09.2009, published on 01.27.2010). The luminaire contains a heat-conducting base and an impact-resistant optically transparent cover, connected to the base by gluing or using screws. A diffuse diffuser is installed inside the ceiling. On the base, by gluing or using rivets, a printed circuit board is fixed on which LEDs with their power circuit, motion and illumination sensors, configured to control the power supply circuit of the LEDs, are placed. Niches with holes for standard fasteners (bolts, screws) designed for installation on a supporting surface (wall, ceiling) are made on the peripheral part of the ceiling.

Known lamp works as follows. The manufacturer sets the parameters of the lamp, namely the range of the motion sensor and the level of illumination depending on the ambient natural light, which determines the brightness of the LEDs. The luminaire is mounted on a supporting surface and connected to a stationary electrical network. When a person appears in the zone of the lamp, the motion sensor supplies power to the LEDs, which light up with a power corresponding to a given level of illumination, and emit light during the entire time of movement in the zone of the lamp. If there is no movement in a given zone of the lamp, the motion sensor turns off the power of the LEDs.

The known technical solution, selected as a prototype, has a relatively low reliability. This is due to the possibility of free access by unauthorized persons to the fasteners that fix the lamp on the supporting surface, and the ability to remove these elements using standard (standard) tools or using vandal devices (master keys, mounts, nippers, etc.), which significantly increases risk of unauthorized dismantling and lamp failure.

Design features of the known lamp provide for the presence (in working condition) of fixing two types: pairwise connection of the lamp elements (shade with base and printed circuit board with base), carried out by gluing, soldering or using fasteners (screws, rivets), and fixing the lamp to the supporting surface using at least two additional fasteners, which leads to a complication of the design of the lamp, including by increasing the number of fasteners, necessary for its functioning, and also complicates the installation of the lamp, respectively increasing its cost.

In addition, the luminaire operation parameters set by the manufacturer are unchanged, which increases the possibility of failure of the luminaire as a result of overheating of the LEDs (when movement is observed in its area for a long time), as well as as a result of emergency situations in stationary power supply networks.

The objective of the proposed utility model is to increase the reliability of the lamp and simplify its design.

The technical result consists in minimizing the risk of failure due to unauthorized dismantling by limiting the access of unauthorized persons to the fasteners and increasing the reliability of fixing the lamp elements with each other while reducing the number of fasteners necessary and sufficient for the functioning of the lamp.

An additional technical result is the reduction of the risk of failure due to violation of the power supply and temperature conditions due to the possibility of monitoring and operational regulation of the parameters of the lamp.

The technical result is achieved by the fact that in a known luminaire containing a base of heat-conducting material, a plafond having through holes for a fastener and connected to the base of the luminaire, a diffuse diffuser, a printed circuit board located in the inner cavity of the luminaire and connected to the base, LEDs with their circuit power supply located on a printed circuit board, motion sensor and light sensor mounted on a printed circuit board with the ability to control the power supply circuit of the LEDs, and a fastener , according to the utility model, the holes for the fastener are made on the ceiling, on the printed circuit board and on the base of the lamp, so that they have a common vertical axis, the hole on the ceiling is placed in the central part of the recess made in the central part of the ceiling, ceiling, printed circuit board and the base are interconnected by means of a fastener passing through these holes and equipped with a countersunk head having a non-standard slot. It is effective to make a recess on the plafond in the shape of a truncated cone, the smaller base of which faces the inner cavity of the lamp, with a hole for the fastener in the central part of the base and the larger base facing out and its diameter is not more than 1/3 of the height of the truncated cone. It is optimal to perform grooves on the basis of the lamp in which the printed circuit board is movably mounted. It is also effective to additionally equip the lamp with a temperature sensor with the ability to control the power supply circuit of the LEDs; micro computers with the ability to control motion, light and temperature sensors, as well as the power supply circuit of LEDs; a microcomputer remote control sensor and an autonomous power source for the LED circuit.

The achievement of the claimed technical result is determined by the following. The design features of the fastener (the presence of a countersunk head with a non-standard slot), together with the peculiarity of its placement on the plafond (in the recess), which allows to “drown” the indicated element in the plafond as much as possible, significantly limit or (in some cases) completely exclude the possibility of access to the fastener the element, as well as the possibility of its removal by unauthorized persons (for example, by squeezing the fasteners with the lever, by using standard standard tools or vandal devices vlennosti). All this significantly reduces the risk of unauthorized (unscheduled) dismantling of the lamp and its failure, which, in turn, leads to an increase in the reliability of the lamp. The shape of the recess on the lampshade (truncated cone) and its parameters create additional obstacles for unauthorized persons to access the fastener and to remove it, which further helps to minimize the risk of unauthorized dismantling and failure of the lamp, further increasing the reliability of the latter.

In addition, the fixation of the lamp elements provided for by the design of each other (the lampshade, the printed circuit board and the base), and the lamp as a whole (to the supporting surface) by means of one fastening element (passing through the holes in these elements), taking into account the particular placement of holes for the specified a fastener (in the central part of the ceiling with a common axis) allows, to minimize the number of necessary and sufficient fasteners, to exclude the possibility of shear rd lamp elements relative to each other, which contributes to the reliability of fixation. All this provides a simplification of the design of the lamp while increasing the reliability of its operation. Simplification of the design of the lamp (in particular, through the use of a single fastener), reduces labor and time costs for its assembly and installation (fastening to the supporting surface), which, in turn, allows you to quickly make minor repairs of the lamp, and simplifies its maintenance.

The execution of the grooves on the basis of the lamp in which the printed circuit board is installed eliminates the need to use additional methods and means (for example, means for gluing, soldering, or additional fasteners) to fix the specified board to the base. This simplifies the design of the lamp and, in combination with the mobility of fastening of the specified board, allows its removal (for example, in the case of routine inspection or urgent repair) without additional labor and time costs, which also simplifies the maintenance of the lamp.

An additional technical result is achieved by supplying the luminaire with additional elements, such as a temperature sensor with the ability to control the power supply circuit of the LEDs, a microcomputer with the ability to control motion, light and temperature sensors, as well as a power supply circuit of the LEDs, a remote control sensor of the microcomputer, which allow timely adjustment of parameters lamp operation, as well as supplying an autonomous power source, ensuring uninterrupted operation of the lamp in emergency situations. All this helps to increase the reliability of the lamp as a whole.

When analyzing the patent and scientific literature, no devices of a similar purpose were found that would have all the features of the claimed utility model in their totality, as reflected in the formula. Thus, the proposed lamp meets the condition of patentability "novelty."

The inventive utility model is illustrated by drawings, where in FIG. 1 shows a general view of the lamp (top view), in FIG. 2 is a cross-section of the luminaire along line AA (side view), in FIG. 3 - base with a printed circuit board (side view), FIG. 4 - embodiment of the lamp, FIG. 5 - fastener (option 1, top view), FIG. 6 - fastener (option 2, top view), FIG. 7 - fastener (option 3, top view).

The lamp contains a base 1 connected to the ceiling 2 (Fig. 1, 2). The base 1 is made of a heat-conducting material, for example, from an aluminum profile or sheet.

The ceiling 2 can be made of a polymer with high mechanical characteristics (for example, polycarbonate, polystyrene, etc.) so that its longitudinal section can be a geometric shape of any shape (for example, square, rectangle, circle, polygon, etc. P.). In the central part of the lampshade 2, a recess 3 is made, for example, in the form of a truncated cone, the smaller base of which is turned inside the lampshade 2, and the diameter of the larger base is 1/3 of its height.

Inside the ceiling 2 is placed a diffuse diffuser 4, which is a plate formed of many biconvex lenses. The plate can be made of glass or any optically transparent polymer (for example, polycarbonate, polystyrene, etc.) and fixed to the inner surface of the ceiling 2, for example, by gluing. Diffuse diffuser 4 can also be made by casting integrally with the ceiling 2.

In the recess 3 of the lampshade 2, a fastener 5 is installed (for example, a bolt, screw) with a countersunk head having a non-standard slot. A non-standard slot can be made in the form of at least one hole having a cross-sectional shape in the form of a circle or a polygon and a longitudinal section shape (passing through the axis of the hole) in the form of a polygon (Fig. 4, Fig. 5, Fig. 6, Fig. 7).

Inside the ceiling 2, a printed circuit board 6 is installed (Fig. 3). The mounting of the printed circuit board 6 can be performed movably by placing the circuit board in the grooves of the base 1 (Fig. 2) or motionless by gluing or soldering. The printed circuit board 6 is made of a dielectric plate, for example of fiberglass or any other insulating material (for example, ceramic).

On the printed circuit board 6 on the surface facing the ceiling 2, there are LEDs with their power circuit (not shown in Fig.) And a motion sensor (not shown in Fig.), And on the surface facing the base 1, there is a light sensor, a sensor temperature (not shown in FIG.), which are configured to control the power supply circuit of LEDs, a microcomputer with the ability to control sensors (not shown in FIG.), a remote control sensor of a microcomputer (not shown in FIG.), as well as an autonomous power source LED circuit (in Fig. not yet en). The power supply circuit of the LEDs is made in the form of printed lines from a layer of foil. The motion sensor, light sensor and temperature sensor can be made optical, acoustic, magnetoelectric, microwave or piezoelectric with different radius of action. As an autonomous power source, a rechargeable battery may be used.

The lamp operates as follows. The operation mode of the lamp is determined by adjusting the settings of the microcomputer from the remote control (if any) or set by the manufacturer:

- sets the level of external illumination at which the LEDs turn on or off (the coefficient of natural illumination at which the LEDs turn on - less than 1%; the coefficient of natural illumination at which the LEDs turn off - over 2%);

- the brightness of the LEDs is set in various modes of operation of the lamp (main mode - up to 15,000 lm; standby mode - 10% of the brightness of the glow in the main mode);

- the temperature level inside the ceiling is set at which the LEDs turn on / off or the brightness of the LEDs is adjusted (the temperature at which the LEDs turn off is above 80 ° C; the temperature at which the LEDs turn on is less than 70 ° C; in the range from 25 ° C to 80 ° C adjustable brightness of the LEDs);

- the operating time of the main mode of operation (from 2 minutes or more);

- sets the range of the motion sensor (from 1 to 10 m).

When the luminaire is connected to a stationary electric network, current flows through the printed lines of the board 6 to the LEDs, as a result of which they begin to emit light. The light flux emitted by the LEDs passes through a diffuse diffuser 4, the biconvex lenses of which diffusely scatter the specified flux in the range of 170 °, which ensures the widest possible coverage area.

During operation, the LEDs are heated, the heat generated by them is removed through the base 1 to the supporting surface (wall or ceiling) on which the lamp is mounted. In the case of prolonged operation of the LEDs and when the temperature inside the ceiling 2 rises to a predetermined microcomputer level, a temperature sensor is activated that limits the power of the LEDs (the LEDs turn off or their brightness decreases). As the temperature inside the ceiling 2 decreases to the level set by the microcomputer, the temperature sensor “removes” the power limitations of the LEDs, as a result of which they light up with a power corresponding to the current mode of operation of the lamp.

During the operation of the luminaire when the illumination of the surrounding space increases (for example, if the luminaire is placed outdoors - with the onset of morning) to a predetermined microcomputer level, the light sensor limits the power of the LEDs (the LEDs turn off or their brightness decreases), and when the illumination decreases (for example, if the lamp is located outdoors - with the onset of the evening) of the surrounding space to a predetermined microcomputer level, the light sensor "removes" the power limitations of the LEDs - no light with a power corresponding to the operating mode of the lamp at the moment.

If the power of the LEDs is turned off (by the light sensor or after the operating time has passed), and there is movement in the area adjacent to it (for example, a person has entered the room), the motion sensor supplies power to the LEDs that light up with a power corresponding to the mode of operation of the lamp in this moment.

In the absence of voltage in a stationary electric network, the LEDs are powered by an independent source, which allows the lamp to be used as an emergency light source.

If it is necessary to carry out minor repairs of the lamp, its dismantling is carried out by authorized persons using a special tool to unscrew the fastener 5 with a non-standard slot.

Thus, the claimed features of the implementation of the lamp determine its reliability and simplicity of design.

Claims (8)

1. A luminaire containing a base made of heat-conducting material, a ceiling having through holes for a fastener and connected to the base of the lamp, a diffuse diffuser, a printed circuit board located in the inner cavity of the lamp and connected to the base, LEDs with their power circuit located on the printed circuit board , a motion sensor and a light sensor mounted on a printed circuit board with the ability to control the power supply circuit of the LEDs, and a fastener, characterized in that the holes for the fastener made on the ceiling, on the printed circuit board and on the base of the lamp, so that they have a common vertical axis, the hole on the ceiling is placed in the central part of the recess made in the central part of the ceiling, the ceiling, the printed circuit board and the base are interconnected by means of a fastener, passing through the indicated holes and equipped with a countersunk head having a non-standard slot. 2. The lamp according to claim 1, characterized in that the recess in the central part of the lampshade is made in the form of a truncated cone, the smaller base of which is facing the inner cavity of the lamp, and the larger base is outward, while the hole for the fastener is made in the central part of the smaller base . 3. The lamp according to claim 2, characterized in that the diameter of the larger base of the recess on the plafond in the shape of a truncated cone is not more than 1/3 of its height. 4. The lamp according to claim 1, characterized in that, on the basis of the lamp, grooves are additionally made in which a printed circuit board is movably mounted. 5. The lamp according to claim 1, characterized in that it is additionally equipped with a temperature sensor mounted on a printed circuit board with the ability to control the power supply circuit of the LEDs. 6. The lamp according to paragraphs. 1, 5, characterized in that it is additionally equipped with a microcomputer mounted on a printed circuit board with the ability to control motion sensors, light, temperature, as well as the power supply circuit of the LEDs. 7. The lamp according to claim 6, characterized in that it is additionally equipped with a microcomputer remote control sensor mounted on a printed circuit board. 8. The lamp according to claim 1, characterized in that it is additionally equipped with an autonomous power source for the LED circuit.

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