Illuminating Device Technical Field

The present invention relates to an illuminating device.

Background Art

The LED technology has advantages such as high efficiency, energy saving and long lifetime and is currently widely used in the illumination technology. In an LED illuminating device, a heat dissipating performance is very important and directly affects a normal operation of the LED illuminating device, and especially there is a need to improve a heat dis ^¬ sipation effect between an LED light engine and a housing of the illuminating device. A heat dissipation device manufac ^¬ tured by a die casting process is usually used in, for exam ^¬ ple, a B- or P-type LED illuminating device, however, the heat dissipation device manufactured by the process has a large weight and has an increased cost due to cost required for machining and surface-treatment, and thus limits the ap ^¬ plication range of the illuminating device. Further, a heat dissipation device manufactured by a process such as insert molding is used, and manufacture cost of an illuminating de ^¬ vice with the heat dissipation device becomes high because of the use of a die casting process during the machining of the heat dissipation device and machining cost in the insert molding .

Summary of the invention

To improve and overcome the above technical problem, the pre- sent invention provides a novel illuminating device in which a heat dissipation device with a more simple design and structure is used so that the illuminating device is easily assembled and connected as a whole and has a reliable heat dissipation effect. Moreover, since an extrusion process is used, the heat dissipation device manufactured by the process has low cost, and a problem of high cost due to, for example, insert molding or die casting is avoided.

An object of the present invention is achieved by an illumi ^¬ nating device comprising a light engine, a housing and a driver contained in the housing, wherein the illuminating device further comprises a heat dissipation device disposed in the housing, the heat dissipation device comprises a sub ^¬ strate for supporting the light engine and an insert ring in thermal-conductive contact with the substrate. As the heat dissipation device is disposed in the housing, a compact and simple structure of the illuminating device can be achieved so that the illuminating device can be designed to be more compact, and moreover, design of an additional heat dissipa ^¬ tion device outside the housing is avoided, and the possibil ^¬ ity of conducting and dissipating heat from the light engine and the driver is achieved by the respective two parts of the heat dissipation device.

In the illuminating device according to the present invention, the substrate and the insert ring are formed separate ^¬ ly. An effect of dissipating heat at different positions can be achieved by the heat dissipation device formed by separate members, and a heat dissipation area can be increased by the plate-shaped and ring-shaped designs to achieve the possibil ^¬ ity of heat dissipation with high efficiency.

Preferably, the substrate is lap-jointed on the insert ring. With such design, the light engine and the driver which also serve as heat sources can be spatially and structurally sepa ^¬ rated from each other and subjected to heat dissipation through different heat conducting paths, and moreover, a compact and simple connection structure can be achieved so that the heat dissipation device is fixed in the housing and that the illuminating device is assembled more conveniently. Preferably, the insert ring is disposed at a periphery of the substrate in a radial direction thereof. With such design, the insert ring provides the possibility of conducting heat in the radial direction and provides the possibility of sur ^¬ rounding the driver so that heat can be ultimately dissipated through, for example, the housing.

Preferably, the insert ring is disposed to surround part of the driver and disposed to be in thermal-conductive contact with the housing. Thus, the insert ring allows the possibil ^¬ ity of dissipating heat from the driver in the circumferen- tial direction, and since the insert ring has a ring-shaped design, the insert ring has a large heat dissipation surface area and can be conveniently mounted and fixed in the housing to achieve the possibility of ultimately dissipating heat through the housing and achieve a reliable heat dissipation effect.

Preferably, each of the substrate and the insert ring is dis ^¬ posed to have a foolproof structure. Such structural design allows the substrate and the insert ring to be mounted and fixed more easily according to design requirements during as- sembly of the illuminating device so that the whole illumi ^¬ nating device is assembled in a more convenient manner.

Preferably, the illuminating device further comprises a heat conducting layer disposed between the substrate and the in ^¬ sert ring and between the insert ring and the housing. Such heat conducting layer provides an additional connecting ac- „

tion for a tolerance gap between the respective parts so that heat conduction between the respective parts can be performed smoothly to achieve a stable heat dissipation effect.

Preferably, the heat conducting layer is designed as a heat conductive oil or potting adhesive. The heat conductive oil or potting adhesive can achieve not only a close connection between the parts such as the substrate, the insert ring and the housing but also smooth heat conduction between the parts .

According to an embodiment of the present invention, the sub ^¬ strate and the insert ring is respectively designed as an ex ^¬ trusion member. With such design, the heat dissipation device formed by the substrate and the insert ring can be machined and produced more easily and can be low in cost, and high ef ^¬ ficiency of heat dissipation is ensured.

Preferably, each of the substrate and the insert ring is made of metal. Such material has a high efficient thermal conduc ^¬ tivity and can be easily machined by extrusion to achieve a high-efficient heat dissipation effect of the resultant heat dissipation device.

Preferably, each of the substrate and the insert ring is made of aluminum. Such substrate and insert ring have a small mass and have a high thermal conductivity so that the heat dissi ^¬ pation device has a high-efficient heat dissipation effect. According to the design of the present invention, the illuminating device further comprises a holder disposed to hold, with the housing, the heat dissipation device therebetween. The holder provides further fixing of the heat dissipation device and ensures effective and firm mechanical connection between the respective parts of the illuminating device.

Preferably, the holder is connected in a form-fitting manner to the substrate. Such connection manner allows the possibil ^¬ ity of reducing the whole volume of the illuminating device so that the whole structure of the illuminating device is more compact and simple, and moreover can achieve the effect of closely attaching the substrate to the light engine to en ^¬ sure a high-efficient heat dissipation effect.

Preferably, the insert ring is arranged on an inner flange of the housing that protrudes inward to the substrate. With such design, the insert ring can be mounted and fixed in the hous ^¬ ing, and a basis is provided for fixing and connection of the substrate which is lap-jointed to the insert ring.

Preferably, the holder comprises first mounting holes, the housing has mounting poles that are provided with third mounting holes, and a fastening structure mounts the holder to the housing through the first mounting holes and the third mounting holes. Therefore, by the first and third mounting holes, the holder and other parts can be assembled more easi ^¬ ly, and the possibility of firm connection between the re ^¬ spective parts of the illuminating device is ensured.

Preferably, the substrate comprises second mounting holes al ^¬ lowing the fastening structure to pass through. This achieves the possibility of connecting the substrate to the housing by the second mounting holes and ensures that the heat dissipa ^¬ tion device can be fixed in the illuminating device.

Preferably, the mounting poles are disposed in the housing and distributed in a circumferential direction of the hous ^¬ ing. The mounting poles provide an effective manner of con- necting and fixing the holder, the substrate and the insert ring to one another so that the plurality of parts can be fixed and connected together in the axial direction.

Preferably, the fastening structure is a bolt structure, and the first mounting holes and the third mounting holes are screw holes. Therefore, the plurality of parts of the illumi ^¬ nating device can be effectively connected and fixed in the axial direction in a simple manner by the bolt structure.

Brief Description of the Drawings

The drawings constitute a portion of the Description for fur ^¬ ther understanding of the present invention. These drawings illustrate the embodiments of the present invention and ex ^¬ plain the principle of the present invention together with the Description. In the drawings, the same part is represent- ed by the same reference numeral. In the drawings,

Fig. 1 is an exploded view of an illuminating device accord ^¬ ing to the present invention; and

Fig. 2 is a sectional view of an assembled illuminating de ^¬ vice according to the present invention. Detailed Description of the Embodiments

Fig. 1 illustrates an exploded view of an illuminating device 100 according to the present invention. The illuminating device 100 consists of a light engine 1, a holder 5, a heat dissipation device 3, a driver 4, and a housing 2 in this or- der in an axial directional thereof. The heat dissipation de ^¬ vice 3 is designed according to the present invention as two separate parts independent of each other, i.e., a substrate 31 and an insert ring 32, the substrate 31 is located between the holder 5 and the insert ring 32 in the axial direction, and the heat dissipation device 3 is disposed as a whole be ^¬ tween the holder 5 and the housing 2, thus the heat dissipa ^¬ tion device 3 can be designed to be held by the holder 5 or clamped between the holder 5 and the housing 2 during assem- bly, which facilitates the formation of a simple and compact connection structure.

Moreover, according to the design of the present invention, the substrate 31 and the insert ring 32 are formed by an ex ^¬ trusion process and made of a material which is preferably aluminum, thus the heat dissipation device 3 has a high effi ^¬ cient thermal conductivity of an aluminum material, an effect of conducting and dissipating heat from the light engine 1 or the driver 4 with high efficiency can be achieved, and mean ^¬ while a problem of high cost in machining and manufacture caused by using a process such as die casting or insert mold ^¬ ing is avoided.

Specifically, a design of a foolproof structure is used in both the substrate 31 of the heat dissipation device 3 and the holder 5 according to the present invention, that is, it is ensured that the substrate 31 is inserted into the holder 5 from only one direction and fixedly connected to the holder 5 during connection of the substrate 31 to the holder 5. Further, the substrate 31 can be designed, for example, to have a shape matching that of the holder 5, and for example, as shown in Fig. 1, a plurality of tooth-like structures are de ^¬ signed in an outer circumferential direction of the substrate 31, and structures such as tooth grooves are designed in an inner circumferential direction of the holder 5 so that the substrate 31 can be inserted in and surrounded by the holder 5 by means of the structures so designed.

Moreover, the illuminating device 100 further comprises a bolt structure K designed, for example, as screws, and the bolt structure K can further connect, as a fastening struc ^¬ ture, the heat dissipation device 3 and the housing 2 through the holder 5. A plurality of first mounting holes Kl are de- signed in a circumferential direction of the holder 5, a plu ^¬ rality of second mounting holes K2 are disposed in a circum ^¬ ferential direction of the substrate 31, and a third mounting hole K3 is provided in each of a plurality of mounting poles 21 disposed in the housing 2. The mounting poles 21 are dis- tributed in the housing 2 in a circumferential direction of the housing 2 and extend along an axial direction of the housing 2, three mounting poles 21 are designed as shown in Fig. 1, and the number of the mounting poles 21 can be of course determined based on the number of the first mounting holes Kl and the second mounting holes K2 respectively dis ^¬ posed in the holder 5 and the substrate 31 so as to ensure that the holder 5 and the substrate 31 can be finally con ^¬ nected to the housing 2 by screws sequentially through the first, second and third mounting holes Kl, K2, K3. The mount- ing poles 21 disposed in the housing 2 can pass sequentially through the insert ring 32 and the second mounting holes K2 disposed in the circumferential direction of the substrate 31 when being assembled, thus a fixed mechanical connection be ^¬ tween the holder 5 and heat dissipation device 3 and the housing 2 can be achieved only by allowing the screws K to pass sequentially through the first and second mounting holes and finally be screwed in the third mounting holes during mounting. In this way, edges at different positions of a cir ^¬ cuit board of the light engine 1 can be, for example, clamped directly by the screws so as to be connected to a surface of the substrate 31, and moreover the substrate 31 and the in ^¬ sert ring 32 of the heat dissipation device 3 are clamped or held between the holder 5 and the housing 2, the substrate 31 is directly lap-jointed to the insert ring 32 and is connect ^¬ ed in thermal contact with the circumference of the insert ring 32, and the insert ring 32 and the housing 2 are connected in thermal contact with each other while being con- nected in direct contact. Furthermore, the driver 4 is par ^¬ tially surrounded by the insert ring 32, thereby providing an effect of, for example, dissipating heat from part of the driver 4 in the circumferential direction.

During assembly, mounting and fixing of the whole illuminat- ing device 100 can be achieved only by mounting the respec ^¬ tive parts in this order in the axial direction as shown in Fig. 1. The illuminating device after assembly is shown in Fig. 2 which illustrates a sectional view of an assembled il ^¬ luminating device according to the present invention. Accord- ing to the design of the present invention, after the illuminating device 100 is assembled, the light engine 1 is fixed and mounted on the surface of the substrate 31 and attached to the substrate 31 so as to achieve absorption and conduc ^¬ tion of heat from the light engine 1 by the substrate 1. The substrate 31 and the insert ring 32 forming the heat dissipa ^¬ tion device 3 are located between the holder 5 and the hous ^¬ ing 2 after assembled so that the heat dissipation device 3 can be wholly contained in the housing 2, and an opening end of the housing 2 is closed in the circumferential direction by the heat dissipation device 3 so that a cavity for accom ^¬ modating the driver 4 is defined by both the heat dissipation device 3 and the housing 2, the purpose of dissipating heat from the driver 4 accommodated therein can be achieved by the heat dissipation device 3 and the housing 2, and further a more compact structure and a simple connection are achieved.

Furthermore, after manufacture, machining, assembly and con ^¬ nection, gaps due to tolerance are formed at joints between the respective parts, and a heat conducting layer C of, for example, a heat conductive oil or potting adhesive is dis ^¬ posed at these joints so as to ensure that heat conduction and heat dissipation between the respective parts are per- formed smoothly and efficiently, and for example, the heat conducting layer C is disposed both between the substrate 31 and the insert ring 32 and between the insert ring 32 and the housing 2 so that an effect of smoothly conducting and dissipating heat between these parts is ensured. The heat conduct- ing layer C so designed can be, of course, also applied to other positions where heat is not conducted smoothly due to a tolerance gap so as to ensure that the illuminating device 100 as a whole has a good heat dissipation effect.

Moreover, the circuit board of the driver 4 can be designed to match the shape of the housing 2 so that after inserted in the housing 2, the driver 4 can be properly contained in the housing 2 and be partially surrounded by the insert ring 32 in the circumferential direction and covered by the substrate 31 in the axial direction after the illuminating device 100 is mounted, thus heat from the driver 4 can be conducted and dissipated directly through the housing 2 and also can be dissipated in the circumferential and axial directions by the insert ring 32 and the substrate 31.

The above are merely preferred embodiments of the present in- vention but not to limit the present invention. It would be understood by those skilled in the art that the present in ^¬ vention may have various alterations and changes. Any altera ^¬ tions, equivalent substitutions, and improvements, within the spirit and principle of the present invention, should be cov- ered in the scope of the present invention. , ,

Reference Numerals

1 light engine

2 housing

3 heat dissipation device 4 driver

5 holder

21 mounting pole

31 substrate

32 insert ring

100 illuminating device

C heat conducting layer

K bolt structure

Kl first mounting hole

K2 second mounting hole K3 third mounting hole