SK6071Y1 - Lamp, especially with the directional flow reflector light - Google Patents

Abstract

Lamp, reflector especially with directional flow of light is formed molded body (1), the upper base is covered with a cover glass (13) sealing the interior of the housing (1), which is mounted a light source (2) connected via power supply (23 ) for external cabling. The light source (2) consists of a thermally conductive base (21), which is mounted in the interior of the body (1) between its base and cover glass (13), it is equipped with at least one LED chip (22) and is equipped with a peripheral contact surface (211), which are adapted for attachment to the shell wall (11) housing (1), the LED chips (22) are connected with power supply (23). LED chips (22) are connected with power supply (23) via at least one auxiliary terminal (4). External contact area (211) thermally conductive base (21) are formed simultaneously with the inner wall of the shell (11) towards the bottom of the lamp or are formed in parallel with the inner wall of the shell (11) towards a cover glass (13). LED chips (22) with the same or different form-making can be arranged on thermally conductive base (21) in rows or other patterns and LED chips (22) can be overlaid directional optical elements (24) formed by lenses made of plastic or plexiglass, or glass or other optical material.

Description

Technical field

The technical solution falls within the field of lighting technology and relates to the construction of a luminaire, in particular a reflector, with a directed flux of light using LED chips, i. j. LEDs integrated on a specific surface in series-parallel connection.

BACKGROUND OF THE INVENTION

At present, various types of lighting devices are used in the field of lighting reflector technology for intensive illumination of the defined area of exteriors or interiors of industrial or residential equipment. As a light source, halogen bulbs, sodium bulbs, energy saving bulbs are generally used in the body of the device so that the light from the source is directed to the desired spatial angle. An example of such a light source is the lamp unit according to EP 1384943. A disadvantage of the current embodiments of conventional halogen lamps is the high operating temperature of the light source, low efficiency and low lifetime. The disadvantage of energy-saving lamps is their relatively low luminous intensity and high purchase price, which in many cases is not proportional to the effect of operation. The aim is therefore to replace these conventional light sources with luminaires or lamps using LEDs, which are commonly used in a wide range of electrical and electronic equipment.

The shape, construction and material of the luminaires containing LEDs are dependent on the user's requirements, i.e. j. environmental conditions and technical conditions in which the lamps will be operated. In connection with these requirements, it is necessary that the choice of construction materials of the equipment must comply primarily with the technical and safety standards of operation, ensure easy installation and maintenance of the luminaire and meet the requirements for environmental aspects of operation. Known examples of luminaire construction include LED light source according to CZ 15825 U1, electric light source according to CZ 9684 U1 or solutions according to US 2010118534 or WO 2010/112419. The construction of the heatsink diodes of the light sources are solved for example in the documents CZ 19147 Ul or CZ 2009-428 A1 and the overall construction of a compact light source in the CZ 8800 Ul file. Other diverse luminaire designs using LEDs are described, for example, in EP 501285, EP 972179, EP 782083, EP 980727, KR 10093909381, CN 101023295, EP 1735845, EP 2211086, EP 2131104 or EP 2211094. and production costly solutions usable only in special environments and conditions.

The aim of the present technical solution is to present a new design of a reflector suitable for a wide range of static and dynamic applications in residential and industrial buildings, which is structurally simple and operationally reliable, has a high lamp life even in continuous operation and low surface operating temperature. high efficiency in the ratio of energy consumption to light output.

The essence of the technical solution

The object is largely achieved by a technical solution which is a luminaire, in particular a reflector, with a directed flux of light, formed by a shaped body whose upper base is covered by a cover glass enclosing the interior space of the body in which the light source is connected via a power supply to the external The principle of the solution is that the light source consists of a thermally conductive base, which is fixed in the inner space of the body between its bottom and cover glass, is equipped with at least one LED chip and is equipped with peripheral contact surfaces adapted for attachment to the walls of the housing, whereby the LED chips are connected to the power supply.

In a preferred embodiment, the LED chips are coupled to the power supply via at least one auxiliary terminal block and the peripheral contact surfaces of the thermally conductive base are shaped parallel to the inner wall of the housing toward the bottom of the lamp or formed parallel to the inner wall of the housing toward the cover glass.

It is also preferred that LED chips with the same or different shape are arranged on a thermally conductive base in rows or other patterns and are overlapped by directional optical elements formed by lenses made of plastic or plexiglass, or glass, or other optical material.

Ideally, the thermally conductive base is formed by a plate and is situated parallel to the cover glass, or the thermally conductive base is profiled stepped down or stepped upward, or concave or convex, or has a sawtooth profile, the source is mounted inside the lamp housing or is mounted on the outer wall of the lamp housing or is located outside the lamp body.

SK 6071 Υ1

The new design of the reflector luminaire achieves high luminous output, which is not dazzling due to the splitting of the radiation surface into individual LED chips, but at the same time produces enough traffic light. The actual arrangement of the individual parts of the luminaire ensures, by means of created thermal bridges, efficient transfer of operating heat from the LED chips to the body and subsequent radiation to the surrounding space. This optimizes the operating conditions for individual LED chips and significantly increases the lamp life and maximizes the light output of the reflector. In addition, the design of the luminaire and the materials used ensure high durability and safety of operation under long-term operating and weather conditions, including shocks and high dust levels in the industrial areas of construction, transport, chemical industry and heavy machinery.

BRIEF DESCRIPTION OF THE DRAWINGS

Specific embodiments of the invention are schematically illustrated in the accompanying drawings, in which: FIG. 1 is a longitudinal axial section of a basic embodiment of a reflector lamp with a power supply located within the lamp body and showing the electrical interconnection of its individual parts; FIG. Fig. 2 is a longitudinal axial section of an alternate embodiment of a reflector having a power supply located outside the housing of the luminaire body and showing the electrical interconnection of its individual parts; Fig. 3 is a longitudinal axial section of another alternative embodiment of a reflector lamp with a power supply located completely outside the lamp body and showing the electrical interconnection of its individual parts; Fig. 4 is a longitudinal axial section of the basic embodiment of the reflector of Fig. 1 showing heat bridges for operating heat dissipation; 5a to FIG. Fig. 5e are schematic longitudinal sections of a reflector equipped with a non-disc thermally conductive base; 6 is a front view of a reflector having a thermally conductive square-shaped base showing alternative examples of using different numbers of differently shaped and spaced LED array assemblies; and FIG. 7 are front views of reflector lamps equipped with a thermally conductive base other than a square outline.

The drawings which illustrate the technical solution and the following examples of specific embodiments do not in any way limit the scope of protection given in the definition, but merely illustrate the nature of the technical solution.

EXAMPLES

In the basic embodiment of FIG. 1 and FIG. 4 is a reflector of a shaped body 1, the casing U of which is formed by a truncated pyramid, in which the lower base passes into a cap 12 closing on one side the inner space of the body 1 and the upper base is covered with a cover glass 13 closing the inner space of the body 1 from the other side . In this case, the body 1 is provided and provided with means (not shown), for example by means of spouts or brackets with connecting openings, for fastening to the support structure of the luminaire (not shown). In the interior of the body 1 is mounted a light source 2, which consists of a thermally conductive base 21 fitted with at least one LED chip 22 connected to a power supply 23, which is connected by unspecified conductors to the main terminal 3 located outside the housing 11 and equipped to allow the fixture outside cable distribution system (not shown). The thermally conductive base 21 is mounted in the upper part of the interior of the body 1 parallel to the cover glass 13 and is designed to cover the entire cross-section of the body 1 and its peripheral contact surfaces 211. preferably in the form of flanges, adapted for abutment and possible attachment to the walls of the housing 11, for example, bent downwards, as seen from the attached figures. The LED chips 22 are also connected by unmarked conductors via at least one auxiliary terminal 4 to the power supply 23, which in the interior of the body f is mounted in a fixing sleeve 5 fixed to the base of the socket 12. The LED chips 22 are preferably covered by directional optical elements 24. for example, a lens made of plastic or plexiglass, or glass, or other optical material.

In the operation of the luminaire, the operating heat generated in the LED chips 22 is discharged through the primary thermal bridge TMI generated by mounting the thermal conductive base 21 to the housing 11 outside the body 1, where the operating heat generated by the power supply 23 is also transferred through the secondary thermal bridge TM2 mounting the power supply 23 in the fixation sleeve 5 and attaching it to the base 12 of the body 1.

The described embodiment is not the only possible construction of the luminaire according to the technical solution, because, as shown in FIG. 2, the power supply 23 can be mounted on the outer wall without affecting the nature of the solution

SK 6071-1 of the casing 11 of the body 1 or the power supply 23 for certain operating conditions of the lamps can be located completely outside the body 1, as shown in FIG. 3. The LED chips 22 need not be obscured by the directional optical elements 24, as shown in FIG. 4 and FIG. 5 and the casing 11 of the body 6 need not be in the form of a truncated pyramid, but can be formed by a truncated cone, a cylinder or a quadrilateral or even other multi-prism. The thermally conductive base 21 can be provided with a circumferential cover frame of various designs and designs. Depending on the requirements of the user and the method of operating the luminaires, the thermally conductive base 21 may be fitted with a single LED chip 22 or into different rows or other patterns of arranged LED chip assemblies 22 with the possibility of combining their shaping, as shown in the examples in FIG. 6 and FIG. 7. The thermally conductive base 21 does not necessarily have to be placed in the upper part of the interior space of the body 6, but according to the type and design of the lamp in any area of the housing 11 between the bottom of the body 8 and the cover glass. with the cover glass 13, but may be differently profiled, for example, stepped as shown in FIG. 5a, 5b, or may be concave or convex convex, as shown in FIG. 5d and 5e, respectively, the saw profile may be as shown in FIG. 5c. The thermally conductive base 21 need not be flat, but may be formed by a grid consisting of mutually perpendicular flat strips, between which the LED chips 22 are arranged. j. the flanges of the thermally conductive base 21 need not be curved downwardly with the inner wall of the housing 11, but for certain luminaire sizes and depending on their location in the interior of the body 5, they may be curved upwardly towards the cover glass £ 3.

Industrial usability

The luminaire according to the technical solution is intended for use in all residential or industrial applications, where high requirements are placed on durability, safety of operation and low operating temperature even under long-term demanding operating conditions, such as engineering, construction, lighting of sports and industrial areas, transport infrastructure equipment, etc.

PROTECTION REQUIREMENTS

Claims (9)

A luminaire, in particular a reflector, with a directed light flux, consisting of a shaped body, the upper base of which is covered by a cover glass (13) enclosing the interior space of the body (1) in which the light source (2) is connected via a power supply (23) to an external cable distribution system, characterized in that the light source (2) consists of a thermally conductive base (21) which is attached in the interior space of the body (1) between its bottom and the cover glass (13) is fitted with at least one LED chip (22) and is provided with peripheral contact surfaces (211) adapted to be attached to the walls of the housing (11) of the body (1), the LED chips (22) being connected to the power supply (23). Light fixture according to claim 1, characterized in that the LED chips (22) are connected to the power supply (23) via at least one auxiliary terminal block (4). Lamp according to claim 1 or 2, characterized in that the peripheral contact surfaces (211) of the thermally conductive base (21) are shaped parallel to the inner wall of the housing towards the bottom of the lamp or formed parallel to the inner wall of the housing (11) towards cover glass (13). Light fixture according to one of claims 1 to 3, characterized in that the LED chips (22) with the same or different shape are arranged on the thermally conductive base (21) in rows or other patterns. Lamp according to one of Claims 1 to 4, characterized in that the LED chips (22) are covered by directional optical elements (24). Lamp according to claim 5, characterized in that the directional optical elements (24) are formed by lenses made of plastic or plexiglass, or glass, or other optical material. Lamp according to one of Claims 1 to 6, characterized in that the thermally conductive base (21) is formed by a plate and is situated parallel to the cover glass (13). Lamp according to one of Claims 1 to 6, characterized in that the thermally conductive base (21) is profiled step-wise downwards or step-wise upwards, or is concave or convex, or has a sawtooth profile. Lamp according to one of Claims 1 to 8, characterized in that the power supply (23) is mounted in the interior of the housing (11) or is mounted on the outer wall of the housing (11) or is located outside the housing (1) of the lamp .