KR102233115B1 - Lens module for led luminaire - Google Patents

Abstract

The present invention relates to a lens module for an LED luminaire including: a lens body including a front surface portion exposed to the outside and a back surface portion having dome-shaped incident portions; a radiation unit facing the back surface portion of the lens body and having a back surface including radiation fins; and an LED substrate disposed between the lens body and the radiation unit and including LED elements installed so as to respectively correspond to the dome-shaped incident portions. A light entry groove having the bottom forming a first incident surface and an inner peripheral surface forming a second incident surface is formed in the top portion of the dome-shaped incident portion. The LED element is disposed so as to face the first incident surface. As a result, light from the LED element moves to the front surface portion of the lens body through the first incident surface and light that has passed through the second incident surface is reflected on the surface of the dome-shaped incident portion and comes out through the front surface portion of the lens body. Accordingly, bottom-view symmetry in all directions can be obtained along with the light distribution characteristics for wide unidirectional diffusion.

Description

Lens module for LED luminaires {LENS MODULE FOR LED LUMINAIRE}

The present invention relates to a lens module for an LED luminaire, and more particularly, to a lens module for an LED luminaire having a symmetrical optical characteristic in front and rear, left and right, and forming light distribution so as to be widely diffused in one direction.

In general, luminaires installed indoors or outdoors to illuminate are mainly sodium lamps, mercury lamps, metal halide lamps, and the like. These lamps consume a lot of power and have a short service life, so the cost of maintenance is high, and there are also problems such as environmental pollution.

In order to solve such a problem, luminaires using LEDs as a light source have recently been adopted and used in most places.

LED luminaires have the advantage of saving energy due to low power consumption compared to conventional light sources, reducing maintenance costs due to their long lifespan, and increasing the design freedom of luminaires while taking up small space due to their small size. It is being applied to lighting.

On the other hand, in terms of optical, the performance of the lighting fixture is determined by whether or not an appropriate amount is sent in the direction in which light is to be sent, and this performance is implemented through light distribution control of the lighting fixture when designing the lighting fixture.

In general, light distribution control is performed using optical components such as reflectors, lenses, and prisms.In the case of LED luminaires, due to the characteristic that the emitted light has straightness, instead of a reflector applied for light distribution control with respect to an existing light source. The optical lens functions as a key component in achieving the light distribution characteristics.

However, since the light emitted from the LED has a narrower distribution of light than other light sources due to strong linearity, the luminaire including the LED has a problem in that the uniformity ratio of illuminance is inferior.

KR 10-1521846 B1 (2015.05.21.announcement)

The present invention has been conceived to solve the problems of the prior art, and an object of the present invention is to provide a lens module for an LED luminaire having a symmetrical optical characteristic in front and rear, left and right, and a light distribution characteristic that is widely diffused in one direction.

In order to achieve the above object, the lens module for an LED luminaire according to the present invention,

A lens body comprising a front portion exposed to the outside and a rear portion on which a plurality of dome-shaped incident portions are formed;

A heat dissipation unit disposed opposite to the rear surface of the lens body and including a plurality of radiating fins on the rear surface; And,

It is disposed between the lens body and the heat dissipation unit and is configured to include an LED substrate including a plurality of LED elements respectively installed to correspond to the plurality of dome-shaped incidence units,

A light entry groove having a bottom forming a first incident surface and an inner circumferential surface forming a second incident surface is formed at the top of the dome-shaped incident surface, and the LED element is disposed in a state opposite to the first incident surface. do.

The first incidence surface is characterized in that it is made of a shape protruding toward the LED element.

The first incident surface is formed in a dome shape, and the second incident surface is formed of a cylindrical hollow inner peripheral surface.

The edge of the opening of the light entry groove is characterized in that it is arranged to be spaced apart from the front surface of the LED substrate.

A boundary is formed between neighboring dome-shaped incidence portions so that the outer shapes of the dome meet each other.

Along the circumference of the LED substrate, the rear surface of the lens body and the front surface of the heat dissipation unit are fixedly coupled with a silicon member therebetween.

In this case, the rear portion further includes a protective sidewall portion formed to surround the dome-shaped incident portions, and the silicon member is interposed between the rear surface of the protective sidewall portion and the front surface of the heat dissipation unit.

When viewing the lens module for an LED luminaire from one direction, a plurality of irregularities extending in one direction are alternately arranged on the front portion of the lens body.

A reflective coating layer is formed on the surface of the dome-shaped incident part.

According to the present invention having the configuration as described above, a lens body comprising a front portion exposed to the outside and a rear portion on which a plurality of dome-shaped incidence portions are formed, is disposed opposite to the rear portion of the lens body, and includes a plurality of radiating fins on the rear surface. Consisting of including a heat dissipation unit and an LED substrate including a plurality of LED elements disposed between the lens body and the heat dissipation unit and installed corresponding to each of the plurality of dome-shaped incidence units, the first incident on the top of the dome-shaped incidence unit A light entry groove having a bottom forming a surface and an inner circumferential surface forming a second incident surface is formed, and the LED device is disposed in a state opposite to the first incident surface, so that the light from the LED device is The light that has passed through the first incident surface and the front of the lens body is reflected from the surface of the dome-shaped incident unit and exits through the front of the lens body. It is symmetric and has the advantage of being able to have a light distribution characteristic that spreads widely in one direction.

In addition, according to the present invention, the first incident surface is formed in a raised shape such as a dome toward the LED element, so that the light emitted from the first incident surface crosses each other, so that more diffused light can be obtained. have.

In addition, according to the present invention, since the second incident surface is formed of a cylindrical hollow inner circumferential surface, there is an advantage in that it is possible to obtain a symmetrical light distribution characteristic and a uniform light dispersion effect in all directions.

In addition, according to the present invention, the edge of the opening of the light entry groove is disposed to be spaced apart from the front surface of the LED substrate, thereby promoting a heat dissipation effect, thereby preventing overheating of the LED substrate.

In addition, according to the present invention, the rear surface of the lens body and the front surface of the heat dissipation unit along the periphery of the LED substrate are fixedly coupled with a silicon member therebetween, so as to prevent the inflow of moisture that causes failure even when used outside. I can.

In addition, according to the present invention, when the lens module for an LED luminaire is viewed from one direction, a plurality of irregularities extending in one direction are alternately arranged on the front portion of the lens body, so that the diffusion effect of light can be further improved. have.

In addition, according to the present invention, a reflective coating layer is formed of a reflective material on the surface of the dome-shaped incidence portion, so that the reflection of light is made more reliably.

1 is a perspective view of a lens module for an LED luminaire according to the present invention.
2 is a front exploded perspective view of a lens module for an LED luminaire according to the present invention.
3 is a rear exploded perspective view of a lens module for an LED luminaire according to the present invention.
4 is a longitudinal sectional perspective view of a lens module for an LED luminaire according to the present invention.
Figure 5 is a view showing the lens body in Figure 1 (a) is a rear perspective view, (b) is a front perspective view.
6 is a cross-sectional view showing a traveling direction of light as a lens module for an LED luminaire according to the present invention.
7 is a light distribution curve of the lens module for an LED luminaire according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 5, the lens module 1000 for an LED luminaire according to the present invention includes a front portion 110 exposed to the outside and a rear portion 120 in which a plurality of dome-shaped incident portions 130 are formed. A lens body 100 consisting of, a heat dissipation unit 200 disposed opposite to the rear surface 120 of the lens body 100 and including a plurality of heat dissipation fins 210 on the rear surface, and the lens body 100 and heat dissipation It is disposed between the units 200 and is configured to include an LED substrate 300 including a plurality of LED elements 310 installed corresponding to each of the plurality of dome-shaped incidence portions 130, the dome-shaped incidence portion 130 ), a light entry groove 133 having a bottom forming a first incident surface 131 and an inner circumferential surface forming a second incident surface 132 is formed, and the LED element 310 is a first incident surface It is positioned in the opening of the light entry groove 133 in a state opposite to 131.

According to this configuration, as shown in FIG. 6, the light from the LED element 310 proceeds to the front portion 110 of the lens body 100 through the first incident surface 131 and at the same time 2 Since the light that has passed through the incident surface 132 is reflected from the surface of the dome-shaped incident part 130 and exits through the front part 110 of the lens body 100, it is symmetrical in the front and rear directions when viewed from the bottom. It is possible to have a light distribution characteristic that is widely diffused.

In particular, the first incident surface 131 is formed in a raised shape toward the LED element 310 so that the light emitted from the first incident surface 131 crosses each other so that further diffused light can be obtained. do.

As an example, it is preferable that the first incident surface 131 has a hemispherical or semi-elliptical cross-sectional shape.

However, it is possible to obtain an effect of dispersing light to some extent only by having a raised shape as another shape.

In addition, it is preferable that the second incident surface 132 is formed of a cylindrical hollow inner circumferential surface for a light distribution characteristic in a symmetrical shape and a uniform light dispersion effect.

It is preferable that the edge of the opening of the light entry groove 133 is disposed to be spaced apart from the front surface of the LED substrate 310 to promote a heat dissipation effect to prevent overheating of the LED substrate 310.

In addition, it is preferable that a boundary is formed between the neighboring dome-shaped incidence units 130 so that the outer shapes of the dome meet each other to show the required light distribution characteristics, and a more compact arrangement is made structurally.

Along the circumference of the LED substrate 300, the rear surface 120 of the lens body 100 and the front surface of the heat dissipation unit 200 are fixedly coupled with the silicon member 500 interposed therebetween. It is desirable to prevent the inflow of moisture, such as rainwater, which is the cause.

For example, as shown in FIGS. 4 and 5, the rear surface portion 120 of the lens body 100 further includes a protective sidewall portion 140 formed to surround the dome-shaped incidence portions 130, and the The silicon member 500 may be interposed between the rear surface of the protective sidewall part 140 and the front surface of the heat dissipation unit 200.

In this case, the height of the protective sidewall portion 140 is formed higher than the height of the dome-shaped incidence portion 130 so that the LED substrate 300 is disposed with a margin between the dome-shaped incidence portion 130 and the heat dissipation unit 200. It is desirable to configure.

An installation flange portion 141 is formed around the lower end of the protective sidewall portion 140 so that the silicone member 500 can be installed with a margin, and the silicone member 500 is installed on the installation flange portion 141. It is desirable to do it.

In this case, an installation groove 141a into which the silicon member 500 is inserted is formed on the rear surface of the installation flange 141, and extends along the length direction of the silicon member 500 at the bottom of the installation groove 141a. It is preferable that the plurality of first sealing grooves 141b are formed to be spaced apart from each other to improve the sealing effect by deforming and sealing the silicone member 500.

A second sealing groove 540 extending along the longitudinal direction of the silicone member 500 is formed on the rear surface of the silicone member 500 to contact the front surface of the heat dissipation unit 200, so that it is sealed by deformation when combined. The effect becomes even greater.

In addition, between the first sealing groove (141b) adjacent to the bottom of the installation groove (141a), a fitting protrusion (141c) that fits into the fitting groove (550) formed in the silicon member (500) is formed. It is preferable to prevent the silicone member 500 from being shaken.

The LED substrate 300 is installed on the front surface of the heat dissipation unit 200 and disposed inside the protective sidewall 140 so that it can be reliably protected from various external influences.

In addition, when viewing the lens module 1000 for an LED luminaire from one direction, the front portion 110 of the lens body 100 has a configuration in which a plurality of irregularities 111 extending in one direction are alternately arranged. It is desirable to further improve the light diffusion effect.

In addition, it is preferable to form or apply a reflective coating layer 135 as a reflective material on the surface of the dome-shaped incidence unit 130 so that the reflection of light is made more reliably.

7 shows a light distribution curve of the lens module 1000 for an LED luminaire according to the present invention.

As shown, it is possible to obtain an orientation characteristic in which the lens body 100 is widely diffused in a longitudinal direction in which more lens bodies 100 are arranged together with the optical characteristics that are symmetrical to the front and rear, left and right.

In the illustrated embodiment, a 2×6 dome type incidence portion 130 is arranged, but various arrangements such as 6×6 and 3×7 are possible.

Of course, in the case of a square arrangement such as 6×6, it is possible to obtain an orientation characteristic that is not only symmetrical in all directions, but also spreads widely.

The embodiments of the present invention are merely exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible within the scope of the following claims.

100... lens body
110... front of the lens body
111... irregularities
120... the back of the lens body
130... domed entrance
131... first entrance plane
132... second entrance plane
133... Optical entry groove
135... reflective coating layer
200... heat dissipation unit
210... heat dissipation fin
300... LED board
310... LED elements
500... silicone absence
1000...Lens module for LED luminaires

Claims (3)

In the lens module for LED luminaires,
A lens body comprising a front portion exposed to the outside and a rear portion on which a plurality of dome-shaped incidence portions are formed;
A heat dissipation unit disposed opposite to the rear portion of the lens body and including a plurality of radiating fins on the rear surface; And,
It is disposed between the lens body and the heat dissipation unit and is configured to include an LED substrate including a plurality of LED elements installed to correspond to each of the plurality of dome-shaped incidence units,
A light entry groove having a bottom forming a first incident surface and an inner circumferential surface forming a second incident surface is formed at the top of the dome-shaped incident surface, and the LED element is disposed in a state opposite to the first incident surface,
Along the circumference of the LED substrate, the rear surface of the lens body and the front surface of the heat dissipation unit are fixedly coupled with a silicon member therebetween, and the rear surface further includes a protective sidewall portion formed to surround the dome-shaped incident portions, the An installation flange portion is formed around the lower end of the protective sidewall portion, an installation groove into which a silicone member is inserted is formed on the rear surface of the installation flange portion, and a plurality of first seals extending along the longitudinal direction of the silicone member are formed at the bottom of the installation groove. The grooves are formed to be spaced apart from each other to deform and seal the silicon member, and a second sealing groove extending along the length direction of the silicon member to contact the front surface of the heat dissipating unit is formed on the rear surface of the silicon member. , A lens module for an LED lamp, characterized in that between the first sealing groove adjacent to the bottom of the installation groove, a fitting protrusion to be fitted into the fitting groove formed in the silicone member is formed. delete delete

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