KR100942138B1 - A condensing lens for led - Google Patents

Abstract

The present invention relates to a condenser lens for LED for condensing light emitted from the LED, wherein the condenser lens has a first incident surface formed above the LED so that the central ray emitted from the LED is incident to the lower side. A second lens portion having a first lens portion having a convex shape toward the face, a second incident surface on which a peripheral ray emitted from the LED is incident, and a reflective surface for total reflection of incident light refracted by the second incident surface; An emission surface formed of a first plane in which the light is refracted from the first plane of incidence of the first lens unit and the plane of reflection of the second lens unit, and having a flat surface for exiting the first lens unit; And the second incidence surface is formed to surround the upper direction of the LED, and the first incidence surface is away from the direction perpendicular to the second incidence surface toward the LED. And the reflective surface is curved to gradually widen from the second incident surface to the exit surface to reflect incident light radiated from the LED and refracted through the second entrance surface to enter the light. Provide a condenser lens for.

Flash, LED, condensing, reflecting surface, incident surface, exit surface

Description

Condensing lens for LED {A CONDENSING LENS FOR LED}

The present invention relates to a light collecting lens for LED, and more particularly, to a light collecting lens that can prevent the loss of the flash light amount in a portable device with a built-in camera module and a flash module.

Recently, as the multifunctionalization of personal portable devices such as PDAs, MP3s, netbooks, and mobile terminals is progressing, portable devices employing built-in camera modules are increasing.

For example, a mobile terminal employing a built-in camera module can be easily found around. In addition, as the adoption of the built-in camera module increases, in order to provide consumers with clearer pictures or videos and to provide various functions, the recent mobile devices employ a flash module so that the user can use the built-in camera module even in low-light conditions. It provides an environment for taking pictures using the flash module.

The camera for a portable device receives light coming through a lens mounted on the camera module to form an image on an image sensor formed on the camera module, and outputs an electrical signal corresponding to an image of a subject formed on the image sensor.

The electrical signal output from the image sensor of the camera module is reproduced as an image corresponding to the electrical signal through a subsequent image processing processor and recorded in a storage device such as a memory.

Such a digital camera module uses a Charge Coupled Device (CCD) or CMOS as an image pickup device instead of a conventional film, and a detailed description thereof will be omitted.

In general, a built-in camera mounted in a mobile terminal or the like adopts a flash function because it is impossible to control the amount of light flowing into the image sensor using an aperture or a shutter spread like a dedicated device such as an analog camera or a digital camera. The structure of a camera is an essential configuration for securing illumination at low light levels.

Therefore, mobile device companies such as mobile terminals are currently working to implement a flash function on the mobile device. Recently, a configuration is known in which an LED which is operable at low power and which is advantageous for miniaturization is adopted as a light emitting body of a flash. LED is a device that has advantages in terms of processing speed, power consumption, lifespan, invention, etc. due to its semiconductor characteristics.

1 is a diagram schematically illustrating a camera module and a flash module mounted in a mobile terminal. Although not shown, the camera module (a) includes a photographing lens unit for forming an image of a subject and an image sensor mounted at a lower end of the photographing lens unit, and provides a light source for a subject in a low-illuminance environment to the periphery of the camera module. A flash module (b) is formed.

However, as shown in Figs. 2A and 2B, the camera module (a) of this structure and the flash module (b) employing the LED have the following problems.

Typically, the camera module (a) employed in a mobile phone has a single field of view with a viewing angle between 30 ° and 60 °. On the other hand, the emission angle of the LED employed in the flash module (b) is about 120 degrees. Therefore, even if it is assumed that the angle of view supported by the camera module (a) is 60 °, as shown by the hatched in Figs. 2a and 2b, approximately half of the flash light is irradiated out of the camera angle of view, so severe light loss Will be generated.

In addition, even if the radiation angle of the flash module (b) is matched to about 60 ° which is the angle of view supported by the camera module (a), since the image pickup device commonly employed in the camera module (a) has a rectangular or rectangular shape, As shown by the hatched regions in Fig. 2C, light loss occurs outside the rectangular image pickup device.

In the case of the camera module (a) having a low resolution of less than one million pixels at the beginning, even if the above-described light loss occurs, a sufficient amount of light is supplied from the LED to the image sensor. While being employed, a sufficient amount of light required for a high pixel image sensor in a low light environment is not provided from the flash.

As part of solving the above-mentioned problems, there is a method of increasing the current supplied to the LED or increasing the number of LEDs mounted on the LED module to compensate for the loss of the conventional flash light amount, but this is from a limited power source of a portable device. In addition to unnecessary waste of the supplied current, there is a problem that increases the manufacturing cost.

The present invention is based on the above-described problems, while radiating the radiation angle radiated from the LED flash employed in mobile devices to correspond to the angle of view of the camera module, and at the same time condenses the radiation light corresponding to the square image mainly employed in the camera module It is an object to provide a condensing lens that can be made.

In order to achieve the above object, the present invention is a condensing lens for LED for condensing light emitted from the LED, the condensing lens is formed above the LED so that the central light rays emitted from the LED is incident A first lens unit having a first incidence surface convex downward, a second incidence surface into which peripheral light rays radiated from the LED are incident, and a reflection surface for total reflection of the incident light refracted by the second incidence surface And an exit surface formed of a flat surface for refracting and exiting the light refracted from the first incident surface of the first lens portion and the reflective surface of the second lens portion, wherein the first incident surface includes: Surrounds an upward direction of the LED, the second incidence surface is formed to surround a lateral direction of the LED, and the second incidence surface faces the LED from a direction perpendicular to the first incidence surface The reflective surface is inclined in a distant direction, and the reflective surface is curved to gradually widen from the second incident surface to the exit surface to reflect incident light that is radiated from the LED and refracted through the second entrance surface to enter the light. It provides a light collecting lens for LED, characterized in that.

Here, the reflecting surface is made of a total reflection condition, wherein the central ray is a ray emitted within a range of ± 45 ° to the vertical optical axis of the LED, the peripheral ray is ± 45 ° relative to the vertical optical axis of the LED Light rays emitted from outside.

At this time, the exit angle of the light exiting from the exit surface is preferably in the range of 30 ° ~ 60 °, the light finally emitted from the exit surface has a rectangular shape.

According to the present invention, not only the radiation angle emitted from the LED used in the mobile device is condensed corresponding to the angle of view of the camera module, but also the light is condensed corresponding to the rectangular shape mainly employed in the image pickup device of the camera module, thereby increasing light utilization efficiency. You can.

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

3 and 4 are views showing the condenser lens 100 for LED flash according to an embodiment of the present invention, Figure 3 is a perspective view showing the appearance of the condenser lens 100 for LED flash, Figure 4 is It is sectional drawing which cut | disconnected the condensing lens 100 for LED flashes based on X-X 'of FIG.

First, as shown in FIGS. 3 and 4, the condensing lens 100 for LED flash according to the present invention has a transparent body 110. In this embodiment, as the main light source, a Lambert type white flash LED 500 was used.

In addition, the body portion 110 is formed so that the space 120 of the rectangular pillar shape to accommodate the LED 500 is formed so that the light emitted from the LED 500 is directly incident to the condensing lens (100).

In addition, the central portion in contact with the upper side of the space 120 of the body portion 110, the first lens unit 200 is convex downward toward the LED 500 to collect light near the center emitted from the LED 500 The first lens portion 200 serves as a first incident surface on which light near the center of the LED 500 is incident.

In addition, the body unit 110 further includes a second lens unit 300 for collecting the ambient light of the LED 500, the second lens unit 300 is a second that the ambient light of the LED is incident and refracted The incident surface 310 and the reflective surface 320 for reflecting the ambient light incident from the second incident surface 310 is included. The reflective surface 320 has a shape that becomes wider toward the exit surface 400 so as to totally reflect the light incident through the second incident surface 310 and forms an outer side surface of the body portion 110.

More specifically, the light rays in the range of about 90 ° to the normal line Y of the LED 500 among the light rays emitted to the LED 500 are preferably in the range of the first lens unit. The incident surface 200 is incident and refracted and exits through the exit surface 400 formed flat. As shown in FIG. 5, the light exit angle emitted through the exit surface 400 via the first entrance surface of the first lens unit 200 corresponds to the camera photographing angle, preferably 30 ° to It is preferable to form the first lens unit 200 to emit within 60 °.

In order to improve the light collecting efficiency, it may be considered to form the center portion of the exit surface 400 aspherical surface corresponding to the incident surface 200, but in this case, there is a problem that the manufacturing cost increases.

In addition, as shown in FIG. 6, about α out of the 90 ° range, preferably α> 85 ° range with respect to the normal normal Y of the LED 500 among the light rays emitted to the LED 500. Rays of light are incident and refracted through the second incident surface 310 of the second lens unit 300 to be totally reflected through the reflective surface 320, and finally emitted through the emission surface 400.

The second incidence surface 310 is formed continuously with the first incidence surface 200, which is approximately perpendicular to the LED at the end of the contact or boundary point with the first incidence surface 200. It is formed downward, preferably with an inclination of approximately 4 °.

In this structure, as the second incident surface 310 is formed to surround the LED 500 formed in the space 120 together with the first incident surface 200, the light from the LED 500 radiates at 180 °. Even if the first incident surface 200, the second incident surface 310 and the reflection surface 320 can be irradiated within the range of the camera photographing angle without loss of light emitted.

FIG. 7 is a view analyzing light efficiency when the LED condensing lens according to the present invention is employed, and as shown in FIG. 7, the light emitted from the LED is concentrated in the center portion. In addition, since the LED condensing lens according to the present invention has a rectangular exit face shape, the light condensed through the condensing lens also has a rectangular shape, which is typically irradiated with flash light according to an image pickup device having a rectangular shape. Therefore, the light loss can be reduced to a minimum.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not for limiting the technical spirit of the present invention but for the description, and the scope of the technical idea of the present invention is not limited by these embodiments.

Therefore, the protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be construed as being included in the scope of the present invention.

1 is a view showing the appearance of a portable terminal employing a flash module and a camera module.

2a to 2c are views showing the light emission angle of the flash module and the photographing angle of view of the camera module.

3 is a perspective view schematically showing an LED flash condenser lens according to the present invention;

4 is a cross-sectional view taken along line X-X 'of FIG. 3;

5 shows a refractive pattern of light rays emitted near the center of the LED.

FIG. 6 illustrates the refraction and reflection pattern of light rays emitted near the periphery of an LED. FIG.

7 is a view showing the efficiency of the LED flash condenser lens according to the present invention.

Claims (5)

In the light condensing lens for LED for condensing light emitted from the LED, The condensing lens, A first lens unit having a shape in which the first incident surface formed above the LED is convex toward the lower side such that the central ray emitted from the LED is incident; A second lens unit having a second incident surface to which peripheral light rays radiated from the LED are incident, and a reflecting surface for totally reflecting incident light refracted by the second incident surface; An emission surface formed of a first plane in which the light is refracted from the first incidence surface of the first lens unit and the reflection surface of the second lens unit, and outputs the light; Wherein the first incidence surface surrounds an upper direction of the LED, the second incidence surface surrounds the lateral direction of the LED, and the second incidence surface faces the LED from a direction perpendicular to the first incidence surface. Inclined in a direction far away, The reflective surface is curved to gradually widen from the second incident surface to the exit surface in order to reflect incident light radiated from the LED and refracted through the second incident surface to enter the first incident surface. Light condensing lens for LED, characterized in that the rectangular shape. The method of claim 1, The reflecting surface is a light condensing lens for the LED, characterized in that the total reflection conditions. The method of claim 1, The central beam is a light beam radiated within a range of ± 45 ° with respect to the optical axis perpendicular to the LED, the peripheral beam is a light beam radiated outside a range of ± 45 ° with respect to the optical axis perpendicular to the LED. Condensing lens. The method of claim 3, Condensing lens for the LED, characterized in that the emission angle of the light emitted from the exit surface is in the range of 30 ° ~ 60 °. The method of claim 4, wherein Condensing lens for the LED, characterized in that the emission profile of the light emitted from the exit surface has a rectangular shape.

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