WO2019212382A1

WO2019212382A1 - General-purpose led lamp

Info

Publication number: WO2019212382A1
Application number: PCT/RU2019/000155
Authority: WO
Inventors: Юрий Борисович СОКОЛОВ
Original assignee: Sokolov Yuriy Borisovich
Priority date: 2018-05-03
Filing date: 2019-03-12
Publication date: 2019-11-07
Also published as: RU2680720C1; WO2019212381A1

Abstract

The invention relates to lighting technology, specifically to general-purpose LED lamps. The technical effect is to simplify the design and improve heat removal by arranging various functional assemblies on a single plate having a metallic base, which is arranged in a common cavity formed by the housing and a diffuser. LEDs and a power source are mounted on the plate, and a threaded base is attached. The metal base of the plate is used as a current conductor. Heat exchange with the environment takes place from the entire surface of the housing and diffuser.

Description

General purpose LED lamp

• Field of technology

The invention relates to lighting equipment, in particular to LED lamps having a printed circuit board and a threaded base (Edison base) for connection to an electric power network.

• Prior art

Many types of LED lamps use a printed circuit board on which, by means of a printed or

volumetric installation placed electronic

elements, for example, elements of electronic

a converter necessary to ensure the operation of the LED lamp.

So far in the traditional way

PCB pin connections

The threaded base is the soldering of the mounting wires.

Quite rarely, solutions are offered that allow connecting the printed circuit board and the base without soldering. However, this entails a complication of the design of the connecting elements, which negatively affects the manufacturability of the LED lamp and its price.

Known LED lamp according to patent CN203477931, (MKI F21S2 / 00, published 03/12/2014), comprising a housing having a through longitudinal cavity, on one side of which a base is fixed, and on the other hand an optically transparent diffuser with a three-dimensional surface; cylindrical radiator whose radial cooling fins are based on the inner surface of the housing; a round printed circuit board with LEDs and components of the power supply circuit mounted on the end surface of the radiator.

The disadvantage of the analogue is the poor heat exchange of the radiator with the housing, due to the small surface of thermal contact and the presence of several assemblies that affect the manufacturability of the design and the cost of the lamp.

In development of this analogue, in the international publication W0 2017/026911 (IPC F21Y 115/10,

published 02.16.2017) a LED lamp is disclosed comprising a housing of heat-conducting

dielectric plastic having through

a longitudinal cavity surrounded by a wall and a removed cylindrical part; base fixed to

remote cylindrical body part; the first

LED circuit board installed

transverse to the axis of the lamp and the surface of which has

thermal contact with the housing; the second elongated

a rectangular board with a power source,

mounted longitudinally to the axis of the lamp. The first and second boards are connected using an electromechanical

contact. To create this, the second board along the edge of the remote end has a perforation made with the possibility of forming a screw connection with a threaded base, during which a reliable electromechanical contact with the first board is formed. Special means for heat dissipation from the cavity of the lamp is not provided, since when screwing the cap the second board is mixed to

base, pressing the contact to the first board, while pressing the first board to the heat sink.

The use of a perforated board to create a wireless connection with a base is disclosed by the author on 04/28/2016 in the publication of the international application

WO2016064295, IPC F21V / 1900.

The disadvantage of the analogue according to WO 2017/026911 is the presence of two boards, as well as the presence in the case

closed under the transverse plate of the air medium, which is heated by heat from the LEDs and from

power supply components assembled on

longitudinal board. The absence of an effective heat sink leads to overheating of the power supply components and an increased thermal load on the LEDs,

leading to their degradation.

Publication W0 2015/171014 describes the design of an LED lamp, which has a body of thermally conductive dielectric material, equipped with a base, a light diffuser, a transverse LED board, a power supply mounted on a longitudinal rectangular FR-4 fiberglass plate connected at one end to the transverse board , and on the other end having a perforated edge connected to the base. The lamp is equipped with a heat sink made in the form of a curved metal strip, on the surface of which a LED board is fixed, and which is installed with the possibility of heat exchange with a longitudinal board, and the rest of the strip surface covered with heat-conducting dielectric material of the housing (WO 2015171014, IPC F1V 19/00, published 12.11.2015).

The disadvantage of the analogue is the lack of manufacturability of the lamp, associated with the presence of two boards, forming operations, several assembly units, the complexity of assembly operations that affect the cost of the lamp, poor heat dissipation from the batteries located on the board from FR4.

The closest analogue is the lamp disclosed in the publication of the international application WO 2017/026911, which coincides with the claimed invention in most significant respects.

The technical result of the claimed solution is to improve heat dissipation and increase

manufacturability, due to the placement of different

functional units on one constructive

element.

• Disclosure of invention.

The invention is characterized by the following

set of features:

A general-purpose LED lamp, comprising: a housing made of heat-conducting dielectric plastic having a through longitudinal cavity,

surrounded by a wall and a removed cylindrical part; a hollow light diffuser mounted on the housing;

a screw base fixed to a remote cylindrical part of the housing; printed circuit board of LEDs and power supply components, the remote edge of which is provided with perforations connected to the internal screw

base surface;

characterized in that

the inner surface of the housing is provided with sections with a flat surface located opposite each other;

the printed circuit board has a metal base and is made in the form of a strip, the flat sections of which are separated by fold zones;

LEDs are mounted on at least one of the flat sections of the printed circuit board, and

at least a portion of the electronic components of the power source and the power connector are mounted to a remote portion of the board, with each flat portion of the board adjacent to the portion of the LEDs,

fixed with the possibility of heat transfer on one of the flat sections of the inner surface of the housing,

the mounting and back surfaces of the printed circuit board are surrounded by the air environment of the body cavities and

diffuser

on the remote cylindrical part of the housing

asymmetric through longitudinal slots are made, while the perforated edges of the remote flat portion of the board are placed in through slots, with the possibility of connection to the inner surface of the base, the central contact of which is made in the form of a pin connected to the power supply connector, and one of the network contacts is connected to the metal base of the board through which current flows.

The inner surface of the housing may be

equipped with two or four flat surfaces located opposite each other.

Two opposite flat sections of the body

used for heat exchange with the board. For this, the flat portion of the printed circuit board adjacent to the portion of the LEDs is fixed by the mounting

side on a flat section of the inner surface of the housing with the force that is created by twisting the cap on the remote perforated edge of the printed circuit board.

The mounting and back surfaces of all sections of the printed circuit board are surrounded by a common air environment.

cavity cavity and diffuser, which allows

to remove heat not only along the metal base of the board, but also through an air medium that has thermal contact with the vast internal surface of the diffuser and the housing. The exception is

mounting surfaces of two sections of the board having direct heat exchange with the inner surface of the housing.

In the case of using more powerful LEDs, to intensify heat transfer, the flat section with LEDs can be equipped with an additional heat sink made in the form of a U-shaped heat-conducting strip installed transversely with the printed circuit board, while the remote ends of the U-shaped heat sink are based on the second pair of flat surfaces in body cavity, pressure to which b it is ensured by twisting the base on the board perforation.

For variability of the direction of radiation,

LEDs can be placed on two adjacent flat sections of the printed circuit board, the angle between which is selected from a mathematical expression:

0 ^ a ^ 180 °, where:

and - the angle between adjacent flat sections of the printed circuit board, angular hail.

The preferred option is such

sweep of the board, as a result of which bending

the selected and bent fragments of the heat-removing sections have a mechanical connection between themselves.

For this, fragments of the heat-removing sections of the board are equipped with short cutouts that are engaged by mutual immersion in each other. Such engagement of fragments of different sections of the board provides rigidity to the entire curved board,

sufficient to uniformly press the heat-removing portions of the board to the inner surface of the case when screwing the cap on the perforation of the board,

guaranteeing reliable thermal contact between

heat exchange surfaces.

• Brief Description of the Drawings

The claimed solution is illustrated by the following graphic materials:

Fig. 1 is a General view of a variant of the LED lamp; figure 2 is a three-dimensional image of a variant of the lamp shown in figure 1, in a parsing; fig.Z-scan of a variant of the printed circuit board, with fixed LEDs and components of the power source;

Fig. 4 is a volumetric enlarged image of the housing of the LED lamp shown in Fig.2;

Fig. 5 is an axial section of a variant of the LED lamp shown in Fig.2;

Fig. 6 is an axial section of a variant of an LED lamp with a parallel arrangement of two flat sections of a printed circuit board with LEDs;

7 is an axial section of a variant of the LED lamp with an inclined arrangement of two flat sections of the printed circuit board;

Fig. 8 is a preferred embodiment of the development of the board with segments on the heat-sink sections;

Fig. 9 is an exploded view of an embodiment of the printed circuit board shown in Fig. 8;

10 is an axial section of a variant of an LED lamp in which the board shown in FIG. 9.

Designations in the figures:

1 - housing.

2 - printed circuit board.

3 - diffuser.

4 - plate additional heat sink, in the form of a strip with bending zones.

5 - screw base.

6 - pin of the central contact of the cap.

7 - remote cylindrical surface of the housing.

8 - power connector for connecting the pin. 9 - slots in the remote cylindrical

body surface.

10- internal flat heat transfer surfaces of the housing.

11 - restrictive elements in the cavity of the housing for fixing the flat heat-exchange sections of the board.

12- remote portion of the board with components

power source (hereinafter, IP section).

13 - perforation at the edges of the IP section.

14- flat section of the board with LEDs (hereinafter, the LED section).

15- power supply components.

16- fold zone of the board.

17 - heat exchange section of the board adjacent to

LED sector.

18- heat exchange section of the board, between the section

LED and IP sector.

19 - selected fragment of the site pos.17.

20 - a selected fragment of the plot pos. 18, adjacent to the plot IP.

/

21- short cut in the selected fragment of the site pos. 17

22 - short cut on the selected fragment 20,

made in the bend zone with the IP site.

23-point engagement of short cuts pos.21 and

Pos. 22.

• Examples of implementation

LED lamp consists of a housing 1 made of heat-conducting plastic with a high electrical resistance having a remote cylindrical part 7, four inner opposite flat surfaces 10, to two of which are pressed sections 17 and 18 of the board 2, which has an aluminum base, which is one of the network conductors, and to the other two, the surfaces of the additional heat sink 4.

The hollow diffuser 3 is mounted on the lamp housing 1.

Two opposite flat sections of the housing 10 are used for heat exchange with the board. For this, the flat sections 17 and 18 of the board adjacent to the flat section 14 of the LEDs are installed in thermal contact with the flat sections 10 of the inner surface of the housing 1 and are positioned using restrictive elements 11 made in the cavity of the housing 1, and the pressing force of the flat sections 17 and 18 is created at the stage of assembly of the lamp when twisting the cap 5 on the perforation 13 of the section 12 of the power source of the printed circuit board 2.

The printed circuit board 2 has several flat sections separated by bending zones 16 and a remote section 12 on which at least a portion of the electronic components 15 of the power source are mounted. The remote section 12 of the board 2 is provided with perforations 13 at the edges, the pitch of which corresponds to the pitch of the screw surface of the base 5.

In a preferred embodiment, the scan of the aluminum printed circuit board 2 is made in the form of a strip, as a result of bending of which the selected fragments 19 and 20 heat sink sections 17 and 18 are interconnected mechanical connection 23 (Fig.9). For the possibility of engagement, the selected fragments 19 and 20 of the heat-removing sections 17 and 18 of the board are equipped with short cutouts 21 and 22 (Fig. 8), which are engaged by mutual immersion in each other.

At section 12 of board 2, at least part of the components of the power supply, including the power connector 8 for connecting to the screw base 5, the central contact of which is made in the form of pin b, is assembled by the SMT mounting method. In this case, the perforated edge 13 of the portion 12 of the board 2 is placed in longitudinal asymmetric slots 9 on the remote cylindrical part 7 of the housing 1, so that the portion 12 of the board is not located on the axis of the base, but is offset relative to the axis to connect the pin b of the central contact of the base 5 s connector 8 of the power source.

If necessary, the surface of fragments 19 and 20 of heat exchange sections 17 and 18 can be used to install some components.

To intensify the heat sink, an additional heat sink 4 can be installed under the flat section 14 of the board, made in the form of a U-shaped plate placed transversely with the printed circuit board 2, while the remote ends of the U-shaped heat sink 4 are based on the second opposite pair of flat surfaces 10 in the cavity housing 1 and positioned using restrictive elements In other embodiments, the lamp LEDs are placed on two adjacent flat sections of the board, separated by a fold zone (Fig. B and Fig.7), which can be located at an angle to each other, the interval of values of which is selected from the expression:

0 <a <180 °, where:

To facilitate the folding of the board in all variants of its execution, the fold zones can be marked with a number of through holes located across the rectangular board.

• Possibility of industrial application

The manufacturing technology of LED lamp elements is widely known, well mastered and provided with high-performance machines, various degrees of automation.

Claims

Claim .

1. General-purpose LED lamp,

containing:

a case of heat-conducting dielectric plastic having a through longitudinal cavity,

a screw base fixed to a remote cylindrical part of the housing;

a printed circuit board with LEDs and power supply components, the remote edge of which is provided with perforations connected to the internal screw

base surface;

characterized in that

diffuser;

at least a portion of the electronic components of the power source and the power connector are assembled in a remote portion of the board, with each flat portion of the board adjacent to the portion of the LEDs being placed on one of the opposite flat sections of the inner surface of the housing with the possibility of heat transfer;

on the remote cylindrical part of the housing

Asymmetric through longitudinal slots are made, while the perforated edges of the remote flat portion of the board are placed in these slots, with the possibility of being connected to the inner surface of the base, the central contact of which is made in the form of a pin connected to a power connector.

2. The LED lamp according to paragraph 1, characterized in that the heat-removing sections of the board contain bent fragments equipped with short cutouts mechanically interconnected by immersion in each other.

3. The LED lamp according to claim 1, characterized in that the LED placement section is provided with an additional U-shaped heat sink installed transversely with the printed circuit board, while the remote ends of the U-shaped heat sink are placed on the second pair of opposite flat surfaces in the cavity

corps.

4. The LED lamp according to paragraph 1, characterized in that the LEDs are placed on two adjacent flat sections of the printed circuit board, the angle between which is selected from a mathematical expression:

0 <a <180 °, where:

and - the angle between adjacent flat sections of the printed circuit board.

5. The LED lamp according to paragraph 1, characterized in that part of the components of the power source is collected on the surface of the fragments of the heat exchange sections.

6. The LED lamp according to paragraph 1, characterized in that a number of through holes are made in the fold zone of the printed circuit board.