WO2013155684A1 - Optically integral led light source and method - Google Patents

Abstract

An optically integral LED light source and a method thereof. Low-power LED elements (5) are distributed on a support rack (4) with holes (6), and light source integration is performed through light-condensing and magnification of a lens (3), to form a linear light source, a planar light source, or a volume light source. The LED elements (5) are distributed on a flat surface, and the light-emitting axis is inclined on the flat surface; or, the LED elements (5) are distributed on a curved surface, and the light-emitting axis is perpendicular to the curved surface. Through holes of the LED elements on a physical position positioning surface are adjacent to each other; a light transmitting medium, an element segregation surface, an electrical connection end through hole are a heat dissipation airflow passageway; integral light sources are classified into a single-condensing-lens type and a multi-condensing-lenses type, and comprise a lighting light source and a light-condensing light source, so as to avoid damage and heat dissipation costs incurred by overheating to existing element integration.

Description

 Light integral LED light source and method

A light-integrated LED light source and method, the low-power LED components are distributed, and the light source is integrated by concentrating and amplifying to form a line light source, a surface light source and a body light source; the components are arranged on a plane, and the light-emitting axis of the component is inclined to a plane; The component is placed on the curved surface, the axis of the component is perpendicular to the curved surface; the LED component is adjacent to the through hole in the physical position positioning surface; the optical medium, the component separation surface, and the electrical connection end through hole are the heat dissipation airflow passage; the integral light source is divided into a single condenser And multi-concentrating mirrors, including illumination source and concentrating source, avoiding the overheat damage and heat dissipation cost caused by the current component integration, industrialization, standardization, serialization, and generalized production; belonging to the field of LED and light source.

Background technique

The current LED light source is a combination of components to dissipate heat, heat dissipation method and structural distribution cause thermal damage of the light source. In order to improve heat dissipation, a heat dissipation component is used to dissipate heat, so that the single component receives heat accumulation from other components and is damaged. Welding, causing the display of the light source points to blink.

According to the invention, the heat of the single component can be prevented from interfering with each other, and the spot of the LED blink can be eliminated.

Summary of the invention

A light-integrated LED light source and method, wherein low-power LED components are distributed on an aperture frame, and the LED light source is integrated by a light-collecting mirror, and is divided into an illumination source and an illumination source.

The invention has the following features:

 1. The eyelet frame includes two types of curved surface and flat surface.

The concentrating method includes two types of single-mirror and multi-mirror modes; single-stage concentrating and multi-stage concentrating two types of illumination.

The light source, the light-passing medium, the condensing mirror, and the cover are combined.

 After the LED single component is independently cooled, the light source is integrated, and the light source body forms a heat dissipation path.

DRAWINGS

Figure 1 is a schematic view of the overall structure,

2 is a schematic view showing the structure of a single-stage single-mirror planar concentrating light source of a cylinder and a square column.

Figure 3 is a schematic view of the structure of a single stage single-mirror planar concentrating light source for a circular table and a prism.

Figure 4 is a schematic diagram of the structure of a single-stage single-mirror concentrating light source with a cylindrical and square column.

Fig. 5 is a schematic view showing the structure of a single-stage single-mirror concentrating light source of a circular table and a prism.

Figure 6 is a schematic view showing the structure of a multi-stage single-mirror planar concentrating light source of a cylinder and a square column.

Figure 7 is a schematic view showing the structure of a multi-stage single-mirror planar concentrating light source of a circular table and a prism. Figure 8 is a schematic view showing the structure of a multi-stage single-mirror concentrating light source of a cylinder and a square column.

Fig. 9 is a schematic view showing the structure of a multi-stage single-mirror concentrating light source of a circular table and a prism.

Figure 10 is a schematic view showing the structure of a single-stage multi-mirror planar concentrating light source of a cylinder and a square column.

Figure 11 is a schematic view of the structure of a single stage multi-mirror planar concentrating light source for a circular table and a prism.

Figure 12 is a schematic view showing the structure of a single-stage multi-mirror curved concentrating light source of a cylinder and a square column.

Figure 13 is a schematic view of the structure of a single-stage multi-mirror curved concentrating light source for a circular table and a prism.

Figure 14 is a schematic view showing the structure of a multi-stage multi-mirror planar concentrating light source of a cylinder and a square column.

Figure 15 is a schematic view showing the structure of a multi-stage multi-mirror planar concentrating light source for a circular table and a prism.

Figure 16 is a schematic view showing the structure of a multi-stage multi-mirror curved concentrating light source of a cylinder and a square column.

Figure 17 is a schematic view showing the structure of a multi-stage multi-mirror curved concentrating light source for a circular table and a prism.

The drawings are as follows:

In Figure 1: 1 is the LED light source cover, the light source cover is uniformly arranged with a plurality of heat dissipation holes on the upper and lower planes, and the side surface of the light source cover is divided into four shapes of a cylindrical shape, a square column shape, a truncated cone shape and a prismatic shape, respectively in FIG. 2 to FIG. 1 is a display; 2 is a lens aperture frame, divided into two types of plane and curved surface, according to the number of lenses, divided into single mirror and multi-mirror frame, the number of holes is larger than the number of lenses; 3 is the lens, according to the optical principle of the lens, Divided into two types of concave and convex,; 4 is the light-emitting element support frame, divided into two types of plane and curved surface, the number of holes is larger than the number of light-emitting elements; 5 is a light-emitting element, can be monochromatic or multi-color; 6 is the cooling hole . In Fig. 2: The light source cover is a cylinder or a square column, has a lens holder, has a lens, and the light-emitting element support frame is flat.

In Fig. 3: The light source cover is a circular or prismatic stage, has a lens holder, has a lens, and the light-emitting element support frame is flat.

In Fig. 4: The light source cover is a cylinder or a square column, has a lens holder, has a lens, and the light-emitting element support frame is a curved surface.

In Fig. 5: The light source cover is a circular or prismatic stage, has a lens holder, has a lens, and the light-emitting element support frame is a curved surface.

In Fig. 6, the light source cover is a cylinder or a square column, and has a multi-layer lens holder. Each lens holder has a lens, and the light-emitting element support frame is flat.

In Fig. 7, the light source cover is a circular or prismatic stage, and has a multi-layer lens holder. Each lens holder has a lens, and the light-emitting element support frame is flat.

In Figure 8: The light source cover is a cylinder or a square column, and has a multi-layer lens holder. Each lens holder has a lens, and the light-emitting element support frame is a curved surface.

In Fig. 9, the light source cover is a circular or prismatic stage, and has a multi-layer lens holder. Each lens holder has a lens, and the light-emitting element support frame is a curved surface.

In Figure 10: The light source cover is a cylinder or a square column, has a lens holder, a lens holder has a plurality of lenses, and the light-emitting element support frame is flat. In Fig. 11: The light source cover is a round table or a prism, and has a lens holder. The lens holder has a plurality of lenses, and the light-emitting element support frame is flat.

In Figure 12: The light source cover is a cylinder or a square column, has a lens holder, a lens holder has a plurality of lenses, and the light-emitting element support frame is a curved surface.

In Figure 13: The light source cover is a circular or prismatic stage, has a lens holder, a lens holder has a plurality of lenses, and the light-emitting element support frame is a curved surface.

In Figure 14: The light source cover is a cylindrical or square column with a multilayer lens holder. The lens holder has a plurality of lenses, and the light-emitting element support frame is flat.

In Figure 15: The light source cover is a circular or prismatic stage. It has a multilayer lens holder. The lens holder has a plurality of lenses, and the light-emitting element support frame is flat.

In Figure 16: The light source cover is a cylindrical or square column with a multilayer lens holder. The lens holder has a plurality of lenses, and the light-emitting element support frame is a curved surface.

In Figure 17: The light source cover is a circular or prismatic stage, has a multilayer lens holder, a lens holder has a plurality of lenses, and the light-emitting element support frame is a curved surface.

Specific form

Component selection principle:

Selection of single light source: Use small power components to increase the heat dissipation area of the electrode legs.

Selection of optical medium: Select air and light-transparent chemical materials.

Selection of condensers: glass, resin, optical materials.

Selection of the cover: The current light and color composite materials are selected.

Flat eyelet holders and curved eyelet holders: machined for perforation or thermoforming, injection molding.

Light source cover: Use light or blackout, single or multi-color, processed into the shape of the figure.

The principles of the invention are:

The electrode of each of the LED elements 5 increases the heat dissipation area.

The connection point between the element electrodes physically corresponds to the position of the eyelet 6 of the light-emitting element support frame 4.

The eyelet of the lens aperture holder 2 corresponds to the aperture position 6 of the light-emitting element support frame 4.

The lens 3 corresponds to an LED element.

An airflow cover is formed around the light source cover 1 and a plurality of heat dissipation holes are uniformly arranged on the upper and lower planes. The patent specification describes that the side surface of the light source cover is divided into four shapes: a cylindrical shape, a square column shape, a truncated cone shape and a prismatic shape, and other similar shapes can realize the light source. The function is no longer described. In the series design, the distance between the LED component and the convex lens should be adjusted according to the magnification of the convex lens and the optical principle.

Claims

 Claims: A light-integrated LED light source and method, wherein low-power LED components are spaced apart on an aperture frame, and the LED light source is integrated by a light-collecting mirror, and is divided into an illumination source and an illumination source.

The light-integrated LED light source and method according to claim 1, wherein the eyelet frame comprises two types of curved surfaces and planes.

The light-integrated LED light source and method according to claim 1, wherein: the concentrating mode comprises two types of single-mirror and multi-mirror modes; and two-stage concentrating and multi-stage concentrating.

The structure of the light-integrated LED light source according to claim 1 is: a light source, a light-passing medium, a condensing mirror, and a cover spacing.

The method for dissipating heat of the light-integrated LED light source according to claim 1 is: after the individual components of the LED are independently dissipated, the light source is integrated, and the light source body forms a heat dissipation path.