PL243267B1 - Optical lighting system of a LED luminaire - Google Patents

Abstract

The light-optical system of the LED luminaire consisting of a matrix with light-emitting diodes equipped with lenses narrowing their distribution and a reflector is characterized by the fact that the light-emitting surface of the matrix is directed towards the movable circular multi-curved reflector (3), which is mounted on a movable arm by means of a servo mechanism (9) around an axis passing through its base, the reflector (3) being open and composed of several curves of a curvilinear parabolic profile. The movable reflector (3), circular, multi-curved, is created by rotating its focusing profile around the symmetry axis of the luminaire by an angle less than 90°. The optical system is not less than one section of the luminaire.

Description

Description of the invention

The subject of the invention is a light-optical system of a LED luminaire with a variable photometric shape, which is used especially for lighting industrial halls, supermarkets, roads, squares and other large spaces.

It is known from the Chinese description CN201120169207.3 LED decoration light, which has a DC power supply, a main controller and LED lighting strips, said main controller consists of a key switch, a crystal oscillator access circuit and a main control chip, said key switch and a crystal oscillator access circuit are respectively coupled to said main control microcircuit, wherein the pulse width modulation terminal of said main control microcircuit provides a variable PWM duty cycle, said crystal oscillator circuit being used to provide a cycle of instructions required for the main control microcircuit, and said a key switch is used to control the operating state of the main control microcircuit, said main controller also comprising a voltage regulation circuit used to regulate the DC supply voltage to the value required by the LED strip light, the input terminal of this circuit being connected to said power supply, and its control terminal is connected to the pulse width modulation terminal of said main control microcircuit, and its output terminal is connected to the input terminal of the LED lighting strip.

From the patent application P.404232 there is known a lighting system for car parks, streets and motorways with the use of a lighting lamp. The system is characterized by the fact that it has a base station, and the lighting lamp is equipped with an IP camera, a Wi-Fi transmission device, a power supply unit, a camera power supply unit and at least one lighting module as a lighting element. The lamps in the system are connected to each other and/or to the base station via a Wi-Fi network, while the base station is connected to the central management station via a broadband link. The arrangement of the lamps in the system is such that each of these lamps is simultaneously within the Wi-Fi signal range of at least three devices for Wi-Fi transmission of other lamps. A lighting lamp consisting of a housing, a lighting element and a power supply unit, characterized by the fact that it has an IP camera, a camera power supply unit, a power supply unit, a Wi-Fi transmission device and at least one lighting module as a lighting element.

Also known from the patent application P.407786 is a lighting system intended for daylighting with LED lamps of large areas, especially supermarkets and production halls, it is made of a photovoltaic cell connected to at least one LED lamp and a power supply maintaining voltage connected to the thus created electric circuit, and a DC and AC to AC converter with a frequency in the range of 1kHz to 100MHz, preferably 100kHz.

The high luminance of LED sources means that in order to reduce direct glare, structural solutions that limit the visibility of the light source are used in situations where the priority is not the precise direction of the light beam, it is possible to position the LED sources in a way that limits their visibility by the observer, e.g. with the direction of light radiation upwards towards the reflector. From the US2008198572A1 patent description, a light-optical system is known, used for lighting roads and squares, using indirect lighting, which consists of a matrix of LED sources placed horizontally, directing the light upwards, and a reflector placed above the LED matrix, directing the light into the lower half-space on the illuminated plane, the system is characterized by asymmetry of light distribution, the main direction of directing the light is deviated from the vertical, and the zone under the luminaire remains underexposed.

From the description of US2011080726A1, a light and optical system of a decorative lamp is known, consisting of a horizontally placed plate with LED sources placed on its upper surface and a rotationally symmetrical parabolic reflector with a single-curvature focusing profile placed above the plate, which is connected to the plate and also acts as a lead-out element the light from the LED sources omnidirectionally, usually in the side direction, and conducts heat from the LED sources to the heat sink located in the upper part of the luminaire, which is additionally equipped with a diffuser. The design does not allow to direct the light mostly vertically downwards.

Also known from the description of US2014268800A1 is the light-optical system of the luminaire used in interior lighting, which consists of a horizontally placed plate with LED sources arranged on its upper surface and a rotationally symmetrical reflector with a sectional profile placed above the plate, and a prismatic cover, which modifies the direction of light coming out of the luminaire. The main direction of light radiation from the luminaire is usually oriented to the side, not down, the luminous flux is directed both into the lower and upper half-space. Directly under the luminaire there is an underexposed zone, this solution does not allow to direct the maximum luminous intensity in the axis of the luminaire.

From the description of CN101566310A, a light-optical system is known, which is based on the use of a linear asymmetric reflector with a sectional profile, which at the same time acts as a heat sink and a base for mounting LED sources, and an elongated plate with LED sources, tilted from the vertical direction. LED sources shine on the reflector, it is mostly indirect lighting, because part of the luminous flux from the source goes directly into space without reflection from the reflector. The luminaire is made of cascaded and overlapping reflector modules with LED light sources, which limits the visibility of the light sources. Instead of a curvilinear parabolic profile, there is a simple approximation of the parabola by flat sections, which translates into reduced precision of the direction of the light beam.

The light-optical system of the LED luminaire consisting of a matrix with light-emitting diodes equipped with lenses narrowing their distribution and a reflector is characterized by the fact that the light-emitting surface of the matrix is directed towards a movable multi-curved circular reflector, which is mounted on a movable arm moved around the axis passing through its base by means of a servo-mechanism that controls the movement of the tendons whose attachment point is located in the middle of the upper part of the reflector. The movable open circular reflector is composed of several curvatures created by rotating its focusing profile around the symmetry axis of the luminaire by an angle less than 90°, creating a curvilinear parabolic profile, and the angular range of the sector depends on the number of luminaire sections. The optical system of the luminaire is not less than one independent section. The light-optical system of the LED luminaire according to the invention is characterized by a matrix with diodes, which is stationary and positioned vertically, and its light-emitting surface is directed towards the reflector, which is mounted on a movable arm moved around the axis by means of a servo-mechanism.

A matrix with diodes and optical elements, i.e. lenses and a reflector, form a light-optical system in which the light from the sources is emitted indirectly onto the working plane through the reflector, and direct radiation is limited by lenses with a properly selected beam angle installed on the diodes. The array of sources with lenses and a reflector constitutes a section of the luminaire. The fitting may be provided with several independent sections, preferably four. The luminaire is made of a set of sections enclosed in a housing that is also a heat sink, arranged on a circular or regular polygon plan. Matrices with sources are placed on the vertical walls of the housing inside and emit a focused light beam inside it in a horizontal direction onto reflectors placed in the center of the housing, additionally the lenses narrow the distribution of sources to obtain indirect radiation from the luminaire, the light from the sources does not go directly to the environment partly conditioned by the need to reduce direct glare, but also provides the ability to control the direction of radiation of the entire luminous flux of light sources. The reflector used in the luminaire is a multi-curvature reflector created by rotating the profile around the symmetry axis of the luminaire, it is a section of the reflector resulting from a full rotation by an angle of less than 90°. The angular range of the slice depends on the number of sections of the housing. The reflector profile consists of two or more separate curvatures constituting segments of a parabola connected to each other, which can be made of materials with different reflective properties. The focus of the reflector component profiles in the base position is in the center of the matrix with the light sources. The reflector is a movable element rotated around an axis passing through its base, parallel to the plane of the matrix with the light sources. The movement of the reflector takes place by tilting it from the base position towards the light sources, which changes the characteristics of the spatial light distribution. Luminaires enable changing the spatial distribution of light through the movement of elements. The main direction of light radiation from the luminaire is directed downwards along the axis of the luminaire, the luminous flux is radiated only into the lower half-space and only through the lower surface of the luminaire, in a variable beam angle, which makes it possible to change the direction of the maximum luminous intensity from the axial direction in the narrow variant to the direction deviated from the the axis of the luminaire with a wide beam, while the illuminated zone under the luminaire is preserved to ensure uniform illumination of the working plane. In addition, thanks to the independent control of both the power of the light sources and the positioning of the reflectors, it is possible to form asymmetric distribution and to achieve the maximum luminous intensity orientation in one of the eight C-half planes in the C-γ system. Importantly, the change in light distribution does not require the replacement of optical system elements with elements with different characteristics. It is implemented by positioning reflectors with a parabolic, double-curvature profile. As a result of the reflector's movement, the light source is moved beyond the focus of the parabola, as a result of which a variable degree of concentration of the light beam is obtained, which can be smooth throughout the entire adjustment range. The position adjustment is carried out by servo-mechanisms that move the reflectors. The fixed support point of a single reflector section is located in its lower part, while the upper part of the reflector is movable. To tilt the upper part of the reflector, servo-mechanisms were used, controlling the movements of the cables, the attachment point of which was located in the middle of the upper part of the reflector. Through the appropriate movement of the reflectors, the appropriate shape of the light distribution of the luminaire is formed.

The subject of the invention in an exemplary embodiment has been shown in the schematic drawings, where Fig. 1 shows a side view of the light-optical system, Fig. 2 shows a top view of the light-optical system, Fig. 3 shows an isometric projection of the light-optical system, Fig. 4 shows top view of the light-optical system of the luminaire with four sections, Fig. 5 shows an isometric projection of the light-optical system of the luminaire with four sections, Fig. 6 shows an example of the luminaire with four sections of the light-optical system, bottom view of the arrangement of elements in the housing, Fig. 7 shows how the reflectors are moved, Fig. 8 shows the wide shape of the light distribution of the fixture.

The light-optical system of the luminaire consists of a matrix 1 with light-emitting diodes equipped with lenses 2 narrowing their distribution and a reflector 3, where the matrix 1 with the diodes is stationary and positioned vertically, and its light-emitting surface is directed towards the reflector 3, which is mounted on a movable arm moved by a servo mechanism 9 around axis 7. Matrix 1 with diodes and optical elements, i.e. lenses 2 and reflector 3, form a light-optical system in which light from sources is emitted indirectly onto the working plane through reflector 3. Direct radiation is limited by lenses 2 with a properly selected beam angle installed on the diodes. The matrix system 1 with diodes and lenses 2 and reflector 3 constitutes a section of the luminaire. The luminaire can be equipped with several independent sections, e.g. four, as shown in Fig. 4 and Fig. 5. The luminaire is made of a set of sections enclosed in a housing 8, which is also a heat sink, arranged on a circular or regular polygon plan. Arrays with sources are placed on the vertical walls of the housing 8 inside it and emit a focused light beam inside it towards the reflectors 3 located in the center of the housing, as shown in Fig. 6. The reflector 3 used in the lighting fixture 8 is a multi-curvature reflector created by rotation profile around the axis of symmetry 6 of the holder 8, it is a segment of the reflector created as a result of a full rotation by an angle less than 90°. The angular range of the slice depends on the number of sections of the housing. The reflector profile consists of two or more separate curves 4 and 5 constituting segments of a parabola connected to each other, which can be made of materials with different reflective properties. The focus of the component profiles of the reflector 3 in the base position is in the center of the matrix 1 with diodes. The reflector 3 is a movable element rotated around the axis 7. To tilt the upper part of the reflector 3, servo-mechanisms 9 were used, controlling the movements of the tendons 10, the attachment point of which was located in the middle of the upper part of the reflector 3. Through the appropriate movement of the reflectors 3, illustrated in Fig. 7, the appropriate shape of the light distribution of the luminaire is formed, e.g. rotationally symmetric wide, illustrated in Fig. 8, rotationally symmetric narrow, illustrated in Fig. 9, symmetrical, illustrated in Fig. 10, asymmetric, illustrated in Fig. 11.

Claims (3)

1. The light-optical system of the LED luminaire consisting of a matrix with light-emitting diodes equipped with lenses narrowing their distribution and a reflector characterized in that the surface of the matrix (1) emitting light is directed towards a movable circular multi-curved reflector (3), which is mounted on a movable arm moved by a servomechanism (9) controlling the movement of the tendons (10), the attachment point of which is located in the middle of the upper part of the reflector (3) around the axis (7) passing through its base. 2. A system according to claim 1, characterized in that it has a movable reflector (3) circular open and composed of several curvatures (4 and 5) formed by rotating its focusing profile around the axis of symmetry (6) of the luminaire by an angle less than 90° forming a curvilinear parabolic profile and the angular range the cutting depends on the number of housing sections. 3. A system according to claim 1, characterized in that the optical system consists of not less than one section of the luminaire (8).