DE112019007944T5 - OPTICAL LENS FOR ILLUMINATION AND ILLUMINATION DEVICE USING SAME - Google Patents

Abstract

The present invention relates to an illumination device using an optical lens for illumination, comprising: an optical lens (100) including a lens part (110) provided with an entrance part (111) adapted to receive light from a side surface, an emitting part (112) configured to emit the entered light, and a total reflection part (113) for the light entering through the entering part (111) to be entirely reflected at the emitting part (112) while various light distribution patterns are formed, and a projection lens part (120) for converting the light emitted from the lens unit (110) into a predetermined light distribution pattern and emitting the same; a plurality of light source parts (130) for emitting the light through the optical lens (100), a housing (210) for accommodating the optical lens (100) and the light source parts (130), and a power supply part (220) for enclosing the light source parts (130 ) to supply with energy. With the present invention, visibility can be improved by generating a light distribution with a wide horizontal angle of view to ensure

Description

[Technical Field]

The present invention relates to an optical lens and an illumination device using the same, and more particularly to an optical lens for illumination capable of improving visibility by generating a light distribution necessary for ensuring forward visibility and a high illuminance value in a specific area has a wide horizontal angle of view, and a lighting device using the same.

[State of the art]

In general, a bicycle is a means of transportation, collectively referred to as a two-wheeled vehicle, which is moved by turning wheels by the power of a person.

In recent years, the vehicle is not simply regarded as a means of transportation, but is widely used for sports, training and leisure.

Cyclists use the bikes, for example, on the way to work or use the bikes for professional leisure activities or for training on vacation or in their free time.

In particular, bicycle riding is increasing in the morning or evening after work, so that when riding a bicycle at night, it is difficult to ensure visibility and there may be an increased risk of accidents, so a lamp (or headlamp) is installed and used on a bicycle.

1 14 is an explanatory view showing a general installation state of a lamp for a bicycle, in which a lamp 20 is mainly installed on a handlebar 11 of a bicycle 10 in use.

2 12 is an explanatory view showing the configuration of a related art lamp for a bicycle, the configuration including a reflector 21, a lamp 22 installed in the reflector 21 for emitting light, and a lens 23 installed on a front side of the reflector 21. so that the light emitted from the lamp 22 can have a predetermined light distribution pattern.

The lamp 20 is made only to simply illuminate a certain area in front of the bicycle, for example, forward in the direction of travel, so the area illuminated by the lamp is very limited, and it is difficult to ensure sufficient safety when riding a bicycle at night.

When a plurality of lamps are installed on the bicycle, there is a problem that the structure of the bicycle as a whole becomes complicated.

From the Korean patent registration no. 10-1534623 (Name of the invention: Light Device for Bicycle Applying Dual Mode) is known a technology capable of freely changing the on/off operation or the brightness of an LED while the bicycle is being ridden.

From the Korean patent registration no. 10-1639531 (Name of the invention: bicycle lighting device) is also known a technology that while the bicycle is being driven, forward visibility according to a driving condition and the driving environment of a bicycle and can ensure that the bicycle can be seen better from behind for other cyclists or vehicles is.

However, the bicycle lighting device known in the related art has a configuration that only improves visibility through brightness control, and the light distribution is concentrated on a specific area; the problem is that it cannot provide a wide spread of light to see your surroundings.

In addition, with a lighting device installed in a mobility device such as an electric scooter, visibility can only be improved by brightness control; however, the problem is that it cannot provide a wide light distribution.

[Epiphany]

[Technical Task]

In order to solve the problem, an object of the present invention is to provide an optical lens for illumination capable of improving visibility by generating a light distribution suitable for ensuring forward visibility and a high illuminance value in a specific area has a wide horizontal angle of view, and a lighting device using this.

[Technical solution]

In order to achieve the above object, an embodiment of the present invention provides an optical lens for illumination, which comprises a lens unit provided with an entrance part that is configured to let light enter from a side surface, an emitter part configured to allow the entered light to be emitted, and a total reflection part so that the light entering through the entrance part is fully reflected to the emitter part while having different light distribution patterns are formed.

In addition, the optical lens according to the embodiment may further include a projection lens unit for converting the light emitted from the lens unit into a specific light distribution pattern and outputting the same.

Further, according to the embodiment, the entrance part may be formed on a long side of the lens unit so that the light enters in a direction perpendicular to a horizontal direction of the lens unit or in a direction inclined by a predetermined angle to the horizontal direction of the lens unit.

Moreover, according to the embodiment, the entrance part may be formed on the long side of the lens unit so that the light enters in a direction perpendicular to a vertical direction of the lens unit or in a direction inclined by a predetermined angle to the vertical direction of the lens unit.

Further, according to the embodiment, the entrance part may include a first entrance part into which a first light enters and/or a second entrance part spaced a predetermined distance from the first entrance part and into which a second light enters.

Furthermore, the emitting part according to the embodiment may include a first emitting part through which the light entering from the first entrance part is emitted and which has a convex curvature in a light emitting direction, and/or a second emitting part which emits the light entering from the second entrance part and has a convex curvature in a light emitting direction.

Further, the total reflection part according to the embodiment may include a first total reflection part that forms a convex curve or a convex aspherical surface in a direction of the first emission part and completely reflects the light entering the first entrance part to the first emission part, and/or a second total reflection part that forms a concave curvature or a concave aspherical surface in a direction of the second emission part and emits the light entering the second entrance part to the second emission part, and/or have a third total reflection part separated from the second total reflection part, in a direction of the second Radiating part forms a concave curvature or a concave aspherical surface and reflects the light entering the second entrance part completely to the second radiating part.

In addition, at least part of the light totally reflected by the second total reflection part according to the embodiment can be totally reflected by a boundary shield and emitted to the second emission part.

Further, according to the embodiment, the second radiating part may further comprise a fourth total reflection part for completely reflecting the light completely reflected by the third total reflection part and a fifth total reflection part configured to form a step in connection with the fourth total reflection part and that completely from the fourth Total reflection part to reflect reflected light completely to the second emission part.

Moreover, according to the embodiment, the fifth total reflection part may be formed on a region where a focal point of the second total reflection part is formed.

berechnet wird, wo a ein Abstand von einer mittleren Achse einer langen Achse der elliptischen Funktion ist und b ein Abstand von einer mittleren Achse zu einer kurzen Achse der elliptischen Funktion ist.Further, a curvature of the total reflection part according to the embodiment may be a curvature of a predetermined portion in a curvature of an ellipsoid obtained from a following equation of an elliptic function $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$

is calculated, where a is a distance from a center axis of a long axis of the elliptic function and b is a distance from a center axis to a short axis of the elliptic function.

In addition, the curvature of the ellipsoid of the first total reflection part according to the embodiment can be a curvature of a portion defining a plane including an optical path of the light completely reflected by the first total reflection part and a vertical direction of the lens unit, and the curvature of the ellipsoid of the second The total reflection part may be a curvature of a portion defining a plane including an optical path of the light totally reflected by the second total reflection part and the vertical direction of the lens unit.

Further, the optical lens may further include a boundary shield that fully reflects part of light reflected from the total reflection part according to the embodiment to form a boundary line in a light distribution pattern of the emission part.

In addition, a focal point of a horizontal curvature of the projection lens unit according to the embodiment can be identical to an imaginary focal point of a horizontal curvature of the total reflection part.

Further, the projection lens unit according to the embodiment may include a first entrance part of the projection lens that forms a first light distribution pattern so that the light input is distributed from the first emission part where a concave curvature is formed in a light emitting direction, and/or a second entrance part of the projection lens, that forms a second light distribution pattern so that the light input is focused from the second emitter part in which a convex curvature is formed in a light input direction.

In addition, a lighting device according to the embodiment using an optical lens for lighting comprises: an optical lens including a lens unit provided with an entrance part configured to let light enter from a side surface, an emission part that is configured to allow the entered light to be emitted, and a total reflection part to allow the light entering through the entrance part to be fully reflected to the emission part while forming various light distribution patterns, and a projection lens unit to focus the light emitted from the lens unit into a specific convert and emit light distribution patterns; a plurality of light source parts for emitting the light to the optical lens, a case for accommodating the optical lens and the light source parts, and a power supply part for supplying power to the light source parts.

Further, a cross-sectional shape of the case in a longitudinal direction according to the embodiment may be a rectangular shape and/or a 'C' shape in which one side is convex and/or a wing shape.

[Beneficial Effects]

The present invention is advantageous in that it is possible to increase safety during nighttime cycling by improving visibility by generating a light distribution that has a wide horizontal angle of view to ensure forward visibility and a high illuminance value in a specific area .

character list

• 1 12 is an explanatory view showing an installation state of a general bicycle lamp.
• 2 12 is an explanatory view showing the configuration of a projection lamp according to a related art.
• 3 12 is a perspective view showing an optical lens for illumination according to an embodiment of the present invention.
• 4 12 is a plan view showing an optical lens for illumination according to the embodiment of FIG 3 .
• 5 14 is a side view showing an optical lens for illumination according to the embodiment of FIG 3 .
• 6 12 is an explanatory view for explaining the arrangement of an entrance part of the optical lens for illumination according to the embodiment of FIG 3 .
• 7 14 is another explanatory view for explaining the arrangement of an entrance part of the optical lens for illumination according to the embodiment of FIG 3 .
• 8th 14 is an explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 .
• 9 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 .
• 10 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 .
• 11 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 .
• 12 14 is an explanatory view showing the light distribution of the optical lens for illumination according to the embodiment of FIG 3 .
• 13 14 is another explanatory view showing the light distribution of the optical lens for illumination according to the embodiment of FIG 3 .
• 14 Fig. 14 is an explanatory view showing an illumination device using an optical lens for illumination. according to an embodiment of the present invention.
• 15 14 is a plan view showing an illumination device using an optical lens for illumination according to the embodiment of FIG 14 .
• 16 14 is a side sectional view showing an illumination device using an optical lens for illumination according to the embodiment of FIG 14 .

[Best Mode]

[Embodiment for the Invention]

In the following, the present invention will be described in detail with reference to preferred embodiments of the present invention and the accompanying drawings, in which the same reference numbers refer to the same elements in the drawings.

Before describing the specific content for carrying out the present invention, it is to be noted that components not directly related to the technical subject matter of the present invention are omitted so as not to detract from the technical subject matter of the present invention.

Also, the terms or words used in the present specification and claims have meanings and concepts consistent with the technical spirit of the invention on the basis that the inventor can define the concept of a corresponding term to best describe the invention.

In the present specification, the phrase that a part "comprises" a certain element does not exclude other elements; rather, it means that it may further include other elements.

Additionally, terms such as "...section", "...group" and "...module" mean an entity that processes one or more functions or operations that are classified as hardware, software, or a combination of both can be.

In addition, the phrase "at least one" is defined as an expression that includes the singular and the plural, and even if the phrase "at least one" does not exist, each element may be singular or plural and may include the mean singular or plural.

Furthermore, each component may be singular or plural depending on embodiments.

Hereinafter, an optical lens for illumination and an illumination device using the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 12 is a perspective view showing an optical lens for illumination according to an embodiment of the present invention. 4 12 is a plan view showing an optical lens for illumination according to the embodiment of FIG 3 , 5 14 is a side view showing an optical lens for illumination according to the embodiment of FIG 3 , 6 12 is an explanatory view for explaining the arrangement of an entrance part of the optical lens for illumination according to the embodiment of FIG 3 , 7 14 is another explanatory view for explaining the arrangement of an entrance part of the optical lens for illumination according to the embodiment of FIG 3 , 8th 14 is an explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 , 9 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 , 10 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 and 11 14 is another explanatory view for explaining the operation of the optical lens for illumination according to the embodiment of FIG 3 .

As in 3 until 11 1, the optical lens 100 for illumination according to an embodiment of the present invention may include a lens unit 110. As shown in FIG.

The lens unit 110 is a member formed of a transparent material to allow entering light to travel along a preset optical path, and the entering part 111 may be formed in the lens unit 110 so that light entering various paths enters from the lens unit 110 side.

The entrance part 111 may be installed so that it protrudes from one side in the longitudinal direction of the body of the lens unit 110 so that the light output from a light source part 130 enters from the side of the lens unit 110, and the entrance part 111 may have a first entrance part 111a and a second entrance part 111b.

The first entrance part 111a receives the light output from the light source part 130, and the entering light travels along a first optical path to form and emit a first light distribution pattern P1, for example.

The second entrance part 111b is installed on the side of the body of the lens unit 110 and spaced a predetermined distance from the first entrance part 111a, and the light emitted from the light source part 130 enters and travels along a second optical path, so that, for example, a second light distribution pattern P2 is formed and released.

In addition, the entrance part 111 may have an entrance part 111-1 so that the light can enter from the light emission direction of the lens unit 110, i. H. the light may enter from a lateral direction orthogonal to a horizontal direction of the lens unit 110 at the long side of the lens unit 110 or a direction inclined at a predetermined angle θ1 from the horizontal direction of the lens unit 110.

In addition, the entrance part 111 may have an entrance part 111 - 2 so that the light can enter from a direction inclined at a predetermined angle θ2 from the horizontal direction of the lens unit 110 .

In addition, the entrance part 111 may have an entrance part 111-3 so that the light can enter from a direction inclined at a predetermined angle θ3 from the vertical direction of the lens unit 110, on the long side of the lens unit 110 orthogonal to the light emitting direction of the lens unit 110

In addition, the entrance part 111 may have an entrance part 111 - 3 so that the light can enter from a direction inclined at a predetermined angle θ4 from the vertical direction of the lens unit 110 .

In addition, the lens unit 110 may have an emission part 112 formed at the distal end of the lens unit 110 in the longitudinal direction of the body of the lens unit 110 so that the light entering the entrance part 111 can be emitted.

The emission part 112 may have a first emission part 112a and a second emission part 112b so that the light entering the first and second entrance parts 111a and 111b can be emitted while traveling along different optical paths.

The first emission part 112a may be configured to emit the light entering from the first entrance part 111a, and may have a convex shape with a curvature occurring at the distal end of the body of the lens unit 110 in the longitudinal direction, i. H. in the light emitting direction.

The second emission part 112b is configured to emit the light entering from the second entrance part 111b, and is installed separately from the first emission part 112a at the distal end of the body of the lens unit 110 in the longitudinal direction.

In addition, the second radiation part 112b may be formed in a convex shape with a curvature formed in the light emitting direction.

Further, the lens unit 110 may have a total reflection part 113 that allows the light entering the entrance part 111 to form various light distribution patterns and to be entirely reflected to the emission part 112 .

The total reflection part 113 may include a first total reflection part 113a that completely reflects the light entering the first entrance part 111a to the first emission part 112a, a second total reflection part 113b that completely reflects the light entering the second entrance part 111b through a boundary shield 114 to avoid the light to the second emission part 112b, and the second total reflection part 113b which completely reflects the light entering the second entrance part 111b to the second emission part 112b.

The first total reflection part 113a fully reflects the light entering the first entrance part 111a so that the optical path to the first emission part 112a is changed, and can be configured as a convex shape with a curvature in the direction of the first emission part 112a or a convex shape with an aspheric be designed surface.

In addition, the first total reflection part 113a forms a light distribution pattern in which the light entering from the first entrance part 111a through the total reflection convex surface is diffused in the direction of the first emission part 112a and completely reflected.

That is, the first total reflection portion 113a forms an imaginary focal point in the first total reflection portion 113a to form a wide light distribution pattern (or wide light distribution). den to form a light distribution pattern with a wide horizontal viewing angle.

The second total reflection part 113b fully reflects the light entering the second entrance part 111b so that the optical path to the second emission part 112b is changed, and can be configured as a concave shape with a curvature in the direction of the second emission part 112b or a concave shape with an aspheric be designed surface.

In addition, the second total reflection part 113b may be configured such that the light entering from the second entrance part 111b through the total reflection concave surface is condensed in the direction of the boundary shield 114 .

In addition, the second total reflection part 113b is arranged so that the focal point of the section curvatures of all sections of the second total reflection part is at a position where the distance from the imaginary point of the horizontal curvature of the second total reflection part 113b is 'R'.

The third total reflection part 113c is installed in division from the second total reflection part 113b, forms a concave curvature or a concave aspherical surface in the direction of the second emission part 112b, and fully reflects the light entering from the second entrance part 111b to a direction of the second emission part 112b to form a condensed light distribution pattern so that the light distribution pattern can be fully reflected.

wo a ein Abstand von einer mittleren Achse einer langen Achse eines Ellipsoids ist und b ein Abstand von einer mittleren Achse zu einer kurzen Achse eines Ellipsoids ist.In addition, the total reflection part 113 may be configured to have a curvature of at least a part of an ellipsoid calculated from the following equation of an elliptic function $$\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$$

where a is a distance from a mean axis of a long axis of an ellipsoid and b is a distance from a mean axis to a short axis of an ellipsoid.

That is, the first to third total reflection parts 113a, 113b and 113c of the total reflection part 113 are designed to have curvature values of some portions below the curvatures of the ellipsoid E.

In this case, the curvature of the ellipsoid E of the first total reflection part 113a is a curvature of a portion defining a plane including an optical path of the light totally reflected by the first total reflection part 113a and a vertical direction of the lens unit 110 .

Also, the curvature of the ellipsoid E of the second total reflection part 113b is a curvature of a portion defining a plane including an optical path of the light totally reflected by the second total reflection part 113b and the vertical direction of the lens unit 110 .

In addition, the lens unit 110 may further include a boundary shield 114 that completely reflects part of the light reflected from the total reflection part 113 to form a boundary line in the light distribution pattern of the emission part 112 .

The boundary shield 114 may include a first boundary shield 114a that forms a boundary line of the light totally reflected from the first total reflection part 113a to the first emission part 112a, and a second total reflection part 113b that forms a boundary line of the light totally reflected from the second total reflection part 113b to the second emission part 112b reflected light forms.

In addition, the lens unit 110 is configured such that the fourth total reflection part 115a and the fifth total reflection part 115b are spaced apart from each other by a predetermined distance at the second emission part 112b of the lens unit 110 while forming a step difference therebetween so that the light from the second or the third total reflection part 113b and 113c moving along a first optical path L1 or a second optical path L2.

That is, the fourth total reflection part 115a completely reflects the light traveling along the first optical path L1 after being completely reflected by the third total reflection part 113c, so that the light enters the fifth total reflection part 115b.

The fifth total reflection part 115b is configured to form a step difference in connection with the fourth total reflection part 115a, and fully reflects the light totally reflected by the fourth total reflection part 115a, so that the light is emitted to the second emission part 112b.

In addition, the fifth total reflection part 115b may be installed at a position where the focal point of the second total reflection part 113b is formed and the position of the fifth total reflection ion part 115b can be calculated from 'A' = 'B' + 'C', where A is the focal length of a second total reflection part, B is a distance between a second total reflection part and a fourth total reflection part, and C is a distance between a fourth total reflection part and a fifth total reflection part.

In addition, the optical lens 100 may be configured to further include a projection lens unit 120 .

The projection lens unit 120 may be configured to convert the light emitted from the lens unit 110 into a specific light distribution pattern to be emitted, and may be configured to be spaced apart from the lens unit 110 by a predetermined distance.

In addition, the focal point of a horizontal curvature of the projection lens unit 120 can be identical to an imaginary focal point of a horizontal curvature of the total reflection part 113 .

Further, the projection lens unit 120 may have a first projection lens entrance part 121 into which the light from the first emission part 112a of the lens unit 110 is input, and a second projection lens entrance part 122 into which the light from the second emission part 112b of the lens unit 110 is input .

The first projection lens entrance part 121 may have a concave shape in which a curvature is formed in a light emission direction.

The first entrance part 121 of the projection lens, which has the concave shape, can form a first light distribution pattern P1 when the light input from the first emission part 112a of the lens unit 110 is emitted, so that a light distribution pattern with a wide angle of view can be formed, as in 12 shown.

The second entrance part 122 of the projection lens may be configured in a convex shape in which a curvature is formed in a light input direction.

The second entrance part 122 of the projection lens, which has a convex shape, can allow the light input from the second emission part 112b of the lens unit 110 to be emitted while forming a second light distribution pattern P2, thereby forming a light distribution pattern with a high illuminance in which the light is condensed into a narrow viewing angle, as in 13 shown.

Next, an illumination device using an optical lens for illumination according to an embodiment of the present invention will be described.

First, repetitive descriptions for the same components will be omitted, and the same reference numbers will be assigned to the same components.

14 12 is an explanatory view showing an illumination device using an optical lens for illumination according to an embodiment of the present invention. 15 14 is a plan view showing an illumination device using an optical lens for illumination according to the embodiment of FIG 14 , and 16 14 is a side sectional view showing an illumination device using an optical lens for illumination according to the embodiment of FIG 14 .

In 3 until 11 and 14 until 16 For example, the lighting device 200 using an optical lens for lighting according to an embodiment of the present invention may include the optical lens 100 , the case 210 , and the power supply part 220 .

The optical lens 100 can have the lens unit 110 with a plurality of entrance parts 111 designed to let various light enter from the side, a plurality of emission parts 112 designed to emit the entering light, and a plurality of total reflection parts 113 , which are designed to allow the light entering the entrance part 111 to form various light distribution patterns and to be fully reflected to the emitting part 112, and the projection lens unit 120 to convert the light emitted from the lens unit 110 into a certain light distribution pattern and emit it .

The light source part 130 is configured to emit the light to the optical lens 110 and installed at a plurality of entrance parts 111 to emit the light to the entrance part 111 . The light source part may be formed of a light emitting device such as a light emitting diode.

The housing 210 is configured so that a storage space is formed therein to accommodate the optical lens 100, the light source part 130, and the power supply part 220. As shown in FIG.

In addition, a cross-sectional shape of the housing 210 in a longitudinal direction may have a rectangular shape and/or a 'C' shape in which one side is convex and/or a wing shape in order to reduce resistance during running. The cross-sectional shape of the housing 210 is preferably a wing shape.

However, the present invention is not limited thereto and it is obvious to those skilled in the art that it can be implemented in various forms.

The power supply part 220 supplies power to the light source part 130 and may include a primary battery or a secondary battery.

In addition, a switch or button may be installed between the power supply part 220 and the light source part 130 to control the on/off operation of the lighting device 200 .

Therefore, the light distribution can be ensured with a wide horizontal angle of view to ensure forward visibility and a high illuminance angle in a specific area, so that visibility can be improved, thereby improving the safety of night riding mobility devices such as bicycles, electric kickboards, electric scooters and motorcycles is increased.

While preferred embodiments of the present invention have been described above, those skilled in the art will understand that the present invention can be variously modified and changed within the spirit and scope of the present invention described in the claims below.

In addition, the reference numerals described in the claims of the present invention are for the purpose of clarity and practical explanation only and are not limited thereto, and in describing the embodiment, the thickness of the lines shown in the drawings or the size of components, etc. are omitted for the sake of clarity and possibly exaggerated for practical explanation.

In addition, the terms described above are defined considering functions in the present invention that may vary depending on user or operator interpretation or custom, so these terms should be interpreted throughout the specification based on the content .

In addition, those skilled in the art of the present invention can make various modifications including the technical spirit of the present invention from the description of the present invention even if not specifically shown or described, and such modifications still fall within the scope of the present invention.

Also, the embodiments described above with reference to the accompanying drawings are for explanation of the present invention, and the scope of the present invention is not limited to these embodiments.

Reference List

100

optical lens

111

entry part entry part

111b

second entry part

112a

first radiating part radiating part

113

total reflection part total reflection part

113b

second total reflection part

114a

first border shield border shield

115a

fourth total reflection part total reflection part

110

lens unit

111a

first

112

radiating part

112b

second

113a

first

114

boundary shielding

114b

second

115b

fifth

120

projection lens unit

121

first entrance part of the projection lens

122

second entrance part of the projection lens

130

light source part

200

lighting device

210

Housing

220

power supply

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• KR 101534623 [0010]
• KR 101639531 [0011]

Claims (16)

Optical lens for illumination, the optical lens comprising: a lens unit (110) provided with an entrance part (111) configured to admit light from a side surface of the entrance part (111), an emitting part (112) configured to emit the entered light and a total reflection part (113) for the light entering through the entrance part (111) to be entirely reflected to the emission part (112) while various light distribution patterns are formed. Optical lens after claim 1 , further comprising a projection lens unit (120) for converting the light emitted from the lens unit (110) into a specific light distribution pattern and emitting the same. Optical lens after claim 1 or 2 , wherein the entrance part (111) is formed on a longitudinal side of the lens unit (110) so that the light is directed in a direction perpendicular to a horizontal direction of the lens unit (110) or in a direction at a predetermined angle (θ1, θ2) to the horizontal direction of the lens unit (110) inclined direction occurs. Optical lens after claim 3 , wherein the entrance part (111) is formed on the longitudinal side of the lens unit (110) so that the light is directed in a direction perpendicular to a vertical direction of the lens unit (110) or in a direction at a predetermined angle (θ3, θ4) to the vertical direction of the lens unit (110) inclined direction occurs. Optical lens after claim 4 , wherein the entrance part (111) has a first entrance part (111a) into which a first light enters, and/or a second entrance part (111b) which is spaced apart from the first entrance part (111a) by a predetermined distance and into which a second light enters. Optical lens after claim 5 , wherein the emitting part (112) comprises a first emitting part (112a) through which the light entering from the first entrance part (111a) is emitted and which has a convex curvature in a light emitting direction, and/or a second emitting part (112b) which which emits light entering from the second entrance part (111b) and has a convex curvature in a light emitting direction. Optical lens after claim 6 , wherein the total reflection part (113) has a first total reflection part (113a) forming a convex curvature or a convex aspherical surface in a direction of the first emission part (112a) and the light entering the first entrance part (111a) completely to the first emission part ( 112a), and/or a second total reflection part (113b) which forms a concave curvature or a concave aspherical surface in a direction of the second emission part (112b) and directs the light entering the second entrance part (111b) to the second emission part (112b ) emits, and/or has a third total reflection part (113c) which is separated from the second total reflection part (113b), forms a concave curvature or a concave aspherical surface in a direction of the second radiating part (112b) and which enters the second entrance part ( 111b) is completely reflected to the second radiating part (112b). Optical lens after claim 7 wherein at least part of the light totally reflected by the second total reflection portion (113b) is totally reflected by a boundary shield (114) and is emitted to the second radiating portion (112b). Optical lens after claim 7 , wherein the second radiating part (112b) further comprises a fourth total reflection part (115a) for totally reflecting the light totally reflected from the third total reflection part (113c) and a fifth total reflection part (115b) adapted to work in conjunction with the fourth total reflection part ( 115a) to form a step and to reflect the light totally reflected from the fourth total reflection part (115a) totally to the second emission part (112b), and the fifth total reflection part (115b) is formed on a region where a focal point of the second total reflection part (113b ) is trained. Optical lens after claim 7 , wherein a curvature of the total reflection part (113) is a curvature of a predetermined portion in a curvature of an ellipsoid obtained from a following equation of an elliptic function $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$

is calculated, where a is a distance from a center axis of a long axis of the elliptic function and b is a distance from a center axis to a short axis of the elliptic function. Optical lens after claim 10 , wherein the curvature of the ellipsoid of the first total reflection part (113a) is a curvature of a portion defining a plane including an optical path of the light completely reflected by the first total reflection part (113a) and a vertical direction of the lens unit (110), and the curvature of the ellipsoid of the second total reflection part (113b) a curvature of a section which defines a plane including an optical path of the light totally reflected by the second total reflection part (113b) and the vertical direction of the lens unit (110). Optical lens after claim 11 , further comprising a boundary shield (114) which completely reflects part of the light reflected from the total reflection part (113) to form a boundary line in a light distribution pattern of the radiating part (112). Optical lens after claim 12 , wherein a focal point of a horizontal curvature of the projection lens unit (120) is identical to an imaginary focal point of a horizontal curvature of the total reflection part (113). Optical lens after Claim 13 , wherein the projection lens unit (120) has a first entrance part (121) of the projection lens forming a first light distribution pattern so that the light input is distributed from the first emission part (112a) in which a concave curvature is formed in a light emission direction, and/or a second entrance part (122) of the projection lens forming a second light distribution pattern so that the light input is focused from the second emission part (112b) in which a convex curvature is formed in a light input direction. Illumination device using an optical lens for illumination, the illumination device comprising: an optical lens (100) including a lens unit (110) provided with an entrance part (111) configured to admit light from a side surface, an emitting part (112) configured to let the entered light can be emitted, and a total reflection part (113) for allowing the light entering through the entrance part (111) to be fully reflected to the emission part (112) while forming various light distribution patterns, and a projection lens unit (120) to allow the light emitted by the lens unit (110) converting emitted light into a specific light distribution pattern and emitting it; a plurality of light source parts (130) for emitting the light to the optical lens (100), a housing (210) for accommodating the optical lens (100) and the light source parts (130) and a power supply part (220) for supplying power to the light source parts (130). lighting device claim 15 wherein a cross-sectional shape of the housing (210) in a longitudinal direction of the housing (210) has a rectangular shape and/or a 'C' shape in which one side is convex and/or a wing shape.

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