GR1009373B - A led lamp destined chiefly for nautical use - Google Patents

Abstract

Novelty: a LED lamp chiefly serving for nautical use is disclosed. Constitution: a hollow cup- or recipient-like body having at its outer wall plural sectors-parts (S1,S2, S3) thermally attached thereto, a bell made of light-permeable material fully covering, by itself, in the assembled state of the invention, the aforementioned hollow body and its integral Led sectors/parts, leaving some free space in-between, the collar 3 of the cooling body which is united with the above hollow body and has a sealing seat 5a provided with the sealing ring 5 towards whose position the sealing collar 2a of the covering bell is moving; the voltage supply of the LED sectors is provided through the internal region of the hollow body.

Description

DESCRIPTION

"MULTI-COMPONENT LED LIGHT.

ESPECIALLY FOR MARINE USE

The invention relates to an LED lamp, in particular for marine use, with a carrier body for attaching a number of LED sectors, a transparent or even semi-transparent cover bell, which, when assembled, covers the carrier body and the LED sectors attached to it.

The invention aims to offer solutions through which it becomes possible to offer a high-power LED lamp with a number of LED arrays, which is also characterized by a long service life used in a wet or dusty environment and which can be properly maintained In case of emergency.

This purpose is served according to the invention by means of an LED lamp, especially for marine use, with

- number of LED sectors,

- bearing body developed as a hollow body of the type of cup or vessel, for placing the LED sectors on its outer wall under conditions of thermal coupling with the bearing body<.>

- cover bell made of permeable technical material and which itself in the assembled state covers the carrier body and the LED sectors attached thereto leaving some intermediate space, and

- cooling body collar which exists united with the hollow body and forms a sealing seat, where

- the cover bell has a collar and the collar in combination with the surrounding bell collar annular element is displaced towards a sealing ring which is seated in the sealing seat of the cooling body collar, and

- the voltage supply of the LED sectors is available through the inner area of the hollow body.

The proposed solution has the advantage of allowing the creation of an LED lamp in which all the LED sectors are shielded from the environment by means of the cover bell, and the inner area of the cover bell is isolated from the environment by means of the sealing installation running along the bearing part, and the sealing installation cooperates with a high-rigidity structure that acts as a heat sink.

According to a particularly preferred embodiment of the invention, the LED lamp is developed so that the sealing ring develops a sealing seat facing the bearing part and a sealing seat facing the cooling body, while the sealing seat facing the hollow body and/or facing the frontal seat of the bell collar is preferably embossed in the axial direction with a continuously running corrugated profile or sealing bulge profile. The axial elevation of this relief is preferably small and if it comes e.g. preferably in just 0.8 to 2 hp. This under the action of assembly forces is preferably elastically compressed substantially completely flat. The sealing ring itself preferably develops at least one planar rectangular cross-section and further preferably additional annular portions axially projecting therefrom which penetrate into corresponding grooves of the heat sink collar.

The bearing body is preferably developed so that it develops first bearing seats which are developed in sequence in the circumferential direction and are structured as rectangular or slightly trapezoidal, which bearing seats are oriented essentially perpendicular to radial axes, the which run perpendicular to the central longitudinal axis of the bearing body. These bearing seats may also be slightly inclined to the longitudinal axis, i.e. e.g. in axial section angled in the range 0 to 15° to this axis.

The bearing body preferably further develops two bearing seats more angled with respect to the longitudinal axis, e.g. in the axial section by 30 to 75°. These bearing seats may be developed and locally flat and simultaneously sunk into a conical seat and form a LED sector assembly seat respectively oriented at an angle in the range of 30 to 75°, preferably by 45° or 60° to the longitudinal axis.

These second bearing seats may be substantially coincident in circumferential corner positions with those edge zones extending between successive circumferentially-directed first bearing seats. Therefore between the LED arrays of the first and the second group a circumferential shift occurs which corresponds to approximately half a circumferential division. This normalizes the radiation characteristics.

Furthermore, the bearing body is preferably configured so that it also develops a third bearing seat, which is a frontal seat of the hollow body oriented substantially perpendicular to the longitudinal axis and on which at least one LED sector is also mounted .

The lamp preferably includes a control facility for controlling the power supply to the respective LED sectors. This control facility may be integral to the lamp, or connected to it by cable. The control installation can also be developed as divided and for example include a component located in the lamp and an external component which will? communicates with the component located on the lamp via cable or wirelessly.

The lamp is preferably further configured so that the LED sectors mounted on the bearing seats are controllable individually or in groups. Control can be directed to the opening/closing function, the brightness, as well as the color of the emitted light. Here it is possible to run programs which e.g. will cause temporal change of light characteristics.

According to a particular aspect of the present invention, the LED lamp is shaped so that on the side facing away from the bell cover of the cooling body collar, a body-casing is provided, for the reception e.g. wiring installation including the control installation or part thereof. This wiring arrangement is preferably inserted through into the body-housing in such a way that the heat dissipation of the wiring arrangement is dissipated through the body-housing's deflectable LED front seat. The body-enclosure is preferably realized as a cup-type component of relatively large volume, the inner region of which communicates with the inner region of the LED carrier body, so that within the space enclosed by these two components strong convective movement is possible through of which heat will be absorbed by the LED body inside the body-casing. This convective motion can be supported by internal blower operation facilities. This blower assembly may in this case be spaced on a printed circuit die carrying the wiring assembly.

The body-casing - placed on the hollow body and the heat sink collar - is preferably made as a component with rotational symmetry and has in the outer peripheral region cooling ribs similar to the heat sink collar.

The LED lamp according to the invention includes according to a further aspect of the present invention preferably a pressure equalization installation provided for the equalization of the pressure prevailing inside the cover bell, the LED carrying body and/or the body-casing placed on the rear side with the ambient pressure, which pressure equalization installation includes a diaphragm. This barrier can be made of a technical material that provides strong protection against moisture, e.g. Goretex material. This makes it possible in the context of the operation of the LED lamp for the heated air to escape through the diaphragm without a significant development of pressure, while during cooling air will be able to re-enter and thus its moisture content will be sufficiently reduced. So what is achieved is that in the course of the operation of this lamp it is dried if necessary as the balance of moisture transfer through the diaphragm favors the exit of water vapor and significantly suppresses the entry of moisture.

Further features and details of the invention will be apparent from the following description taken in conjunction with the drawings. These show:

Figure 1 is an exploded perspective view to explain the structure of an LED lamp according to the invention

Figure 2 perspective overall view of the LED lamp according to the invention

Detailed description of the figures

The image according to Figure 1 shows in the form of an exploded image an LED lamp according to the invention, more specifically for marine use, with a number of LED sectors, (S1), (S2), (S3), carrying body (1) developed as hollow body, for placing the LED sectors (S1), (S2), (S3), cover bell (2) made of transparent material and which in the assembled state covers the carrier body (1) and the LED sectors attached to it ( S1), (S2), (S3), and a cooling body collar (3) which develops a sealing seat, while the cover bell (2) has a collar (2a), and the bell collar (2a) combined with an annular element ( 4) surrounding the bell collar (2a) is pressed against a sealing ring (5), which rests on the sealing seat of the cooling body collar (3), and through the sealing installation is sealingly connected to the front side of the cooling body collar ( 3), and the voltage supply of the LED sectors (S1), (S2), (S3) by is given through the inner area of the bearing body (1).

Through this development it becomes possible, as mentioned in the introduction, to provide an LED lamp in which all the LED sectors (S1), (S2), (S3) will be shielded against the environment by means of the cover bell (2), and the inner area of cover bell (2) is protected against the environment by means of a sealing installation (5) running along the bearing part, and the sealing installation (5) cooperates with a highly rigid structure that acts as a heat sink.

The sealing ring (5) develops a sealing seat (5a) facing the bell collar (2a) and a sealing seat (5b) facing the heat sink (3), while the sealing seat (5b) facing the heat sink collar (3) ) is embossed in the axial direction.

The bearing body (1) develops first bearing seats (T1) developed successively in the circumferential direction and shaped as rectangular or slightly trapezoidal, which bearing seats (T1) are oriented essentially perpendicular to radial axes running perpendicular to a central longitudinal axis X of the bearing body (1).

The bearing body (1) further develops second bearing seats (T2), which sink into a conical seat (T2K) and build LED sector assembly seats which are each oriented at an angle in the range of 30 to 60° to the longitudinal axis X.

The second bearing seats (T2) coincide in terms of their circumferential angular* positions essentially with those of the edge zones (K1) which extend between successive in the circumferential direction first bearing seats (T1).

The bearing body (1) develops a third bearing seat (T3), which is a frontal seat of the hollow body (1) oriented essentially perpendicular to the longitudinal axis X and in which an LED sector (S3) is also placed.

The LED sectors (S1), (S2), (S3) are coupled to the power supply via cables mounted on a printed circuit board. (6). The wires run inside the hollow body (1). The power electronics form part of a control installation, to control the power supply to the respective LED sectors (S1), (S2), (S3). The LED sections (S1), (S2), (S3) mounted on the bearing seats (T1), (T2), (T3) are controlled individually or by groups.

On the side of the cooling body collar (3), facing away from the cover bell (2), a body-housing (7) is located, made as a rotating part, for the reception of the printed circuit matrix (6) and the wiring installation based on it, not shown further . The housing-body (7) is equipped with cooling ribs (7a). The hollow body collar (3) is also provided with cooling ribs (3a). The body-casing (7) and the heatsink collar are machined from technical aluminum material and anodized on the outside. The main part of the precision structures of the lamp is realized in these turning parts. The bearing body is made as a cast part from technical material aluminum or copper and preferably further processed only locally, e.g. to provide flat bearing seats for the arrays (S1), (S2), (S3) and for close thermal coupling with the heatsink collar (3).

The annular element (4) surrounding the bell is preferably made as a precision cut part from NIRO sheet metal. The bell collar (2a) preferably sits recessed within an inner circumferential groove of the hollow body collar. The annular element (4) rests, when the fastening screw that penetrates the annular element is inserted in the maximum position, on a front seat (3b) of the hollow body collar (3), so that a defined axial loading of the sealing ring (5) is achieved without the bell collar (2a) being overloaded or asymmetrically loaded.

The lamp according to the invention further comprises a pressure equalization installation (8), to equalize the pressure prevailing inside the cover bell (1) with the ambient pressure, which pressure equalization installation (8) is in this case a diaphragm.

The operation of the further sub-components shown in this image, e.g. of the cable passage opening (9), the visor (10), the further sealing (11), the screws (12), (13) and (14) is self-evident to the expert. The screws (14) are located in recesses (15) which have been opened in the cooling ribs (7a). Thus, the screws (7a) can be realized as short in the axial direction. These screws (15) clamp the body-housing (7) onto the seal (11) and the heat sink collar (3), as well as the visor (10).

The picture according to Figure 2 shows the above described LED lamp in an assembled state. LED arrays (S1), (S2), (S3) are oriented along the longitudinal axis as sketched, i.e. arrays (S1) are oriented almost parallel to the longitudinal X axis, arrays (S2) are oriented at an angle and arrays (S3) are oriented perpendicular to the longitudinal X axis. LED arrays (S1), (S2), (S2) are surrounded by bell (2). Heat dissipation is mainly through the hollow body (1) which is thermally coupled to the hollow body collar (3) and the casing (1). In addition, heat transfer from the bearing zones of the LED arrays takes place through internal convection inside the LED lamp.

In the axial intermediate region between the anterior bearing seat (T3) and the conical mantle (T2K) a further ring of cooling nerves is developed. This element favors heat dissipation in the atmosphere surrounding the bell (2) which consequently cools on the inner wall of the bell (2). The LED lamp shown here according to the invention is preferably inserted so that its bearing seat (T3) faces downwards. The LED lamp can also be inserted in oblique positions or sometimes so that the bearing seat (T3) faces upwards, and in this case the heat dissipation is lower. Convection in the inner wall of the lamp, especially the hollow body can be supported to the maximum extent by means of a small fan. In this case, even with the placement of an overhead head, i.e. when the bearing seat (T3) faces upwards, good heat transfer to the body-casing (3) results. It is also possible to provide further structures in the inner region of the lamp, which support heat transfer, e.g. the so-called Heatpipes can be placed in the inner area of the bearing body (1) and the casing body (7).

The wiring can be arranged so that from each LED element corresponding lines can be plugged into the power outputs of the circuit mounted on the matrix (6). It is also possible for the wiring to be implemented via a small cable harness or flexible matrix. The LED arrays (S1), (S2), (S3) are preferably connected to the hollow body (1) in such a way that there is good thermal coupling with this structure. Retaining elements can also be provided there which will allow easy, i.e. tool-free, assembly and disassembly of the LED arrays. Thus it is possible to match the construction structure so that the LED arrays are accessible through easy disassembly of the bell (2) and can then be replaced without further opening of the lamp, as the corresponding connections, contacts, plugs, cables will be accessible simply by removing the corresponding LED array.

The special fixing and sealing of the bell (2) through the use of the above-described sealing installation (5) allows multiple disassembly of the bell (2) without affecting the sealing action. By means of the described and illustrated structure, replacement of the LED arrays can be carried out, even by ignorance, without the need for spare parts in relation to the sealing.

The bell collar (2a) sinks into a receiving groove of the cooling body collar. The rear side of the collar (2a) on which the heatsink collar is deflected coincides, preferably with some overhang corresponding to the desired sealing dip, with the flat front seat of the heatsink collar. When the annular element (4) is assembled, it displaces the bell collar (2a) towards the elastomeric seal (5) mounted inside the heatsink collar. When the intended tightening torque is reached on the screw (12) passing through the annular element (4), the annular element (4) is seated on the face seat of the heat sink collar (3) and the seal (5) is subjected to structurally defined pressure without the bell collar (2a) is unbalanced or overloaded.

Claims (9)

1. LED lamp, in particular for marine use, having: - number of LED sectors, (S1), (S2), (S3) - bearing body (1) developed as a cup or vase type hollow body, for placing the LED sectors (S1), (S2), (S3) on its outer wall, - cover bell (2) made of permeable technical material and which itself in the assembled state covers the carrier body (1) and the attached LED sectors (S1), (S2), (S3) leaving an intermediate space, and - cooling body collar (3) which develops a sealing seat (5a), where - the cover bell (2) has a collar (2a) and the collar (2a) combined with surrounding the bell collar (3) annular element is displaced towards a sealing ring (5) which is seated in the sealing seat of the cooling body collar (3) , and - or voltage supply of the LED sectors (S1), (S2), (S3) is available through the inner area of the hollow body. 2. LED lamp according to claim 1 characterized in that the sealing ring develops a sealing seat (5a) facing the bell collar (2a) and a sealing seat (5b) facing the heatsink collar (3), where the sealing seat (5b) facing the heatsink collar (3) is embossed in the axial direction with microlamellas. 3. LED lamp according to claim 1 or 2 characterized in that the bearing body (1) develops first bearing seats (T1), (T2), (T3) which are developed successively in the circumferential direction and are structured as rectangular or slightly trapezoidal, where these bearing seats are oriented substantially perpendicular to radial axes, which run perpendicular to the central longitudinal axis of the bearing body 4. LED lamp according to at least one of claims 1 to 3, characterized in that the bearing body (1) develops second bearing seats which sink into a conical seat and structure LED sector assembly seats which are each oriented at an angle in the range of 30 to 60° to the longitudinal axis. 5. LED lamp according to at least one of claims 1 to 4 characterized in that the second bearing seats coincide in their circumferential corner positions substantially with those edge zones which extend between successive circumferentially directed first bearing seats. 6. LED lamp according to at least one of claims 1 to 5 characterized in that the bearing body (1) develops a third bearing seat which develops a frontal seat of the hollow body oriented essentially perpendicular to the longitudinal axis and to which it is also plugged at least one LED sector. 7. LED lamp according to at least one of claims 1 to 6, characterized in that a control installation is provided for controlling the supply of power to the respective LED sectors. 8. LED lamp according to at least one of claims 1 to 7, characterized in that the LED (S1), (S2), (S3) sectors (T1), (T2), (T3) mounted on the bearing seats are controllable individually or in groups. 9. LED lamp according to at least one of claims 1 to 8, characterized in that a body-housing (7) is provided on the side of the cooling body facing away from the cover bell for the installation of wiring. 10: LED lamp according to characterized in that the p-body with cooling ribs (7a) and/or that provision (8) for equalizing the covering pressure (2) with the ambient pressure pressure (8) comprises a diaphragm. at least one of claims 1 to 9 casing (7) is also provided with a pressure equalization facility prevails inside the bell, wherein the equalization facility