KR20200120228A - LED light fixture with dispersive lens - Google Patents

Abstract

The present invention relates to an LED lighting fixture. An object of the present invention, in the LED device mounted on a PCB of an LED module accommodated in a lamp housing, is to provide the LED lighting fixture capable of satisfying the lighting fixture installation criteria by maximizing side illumination while using minimum energy through the structural features of a dispersion lens of the present invention which surrounds each of the LED devices and is mounted. According to the present invention, the LED lighting fixture includes: the LED module in which a plurality of LED devices are disposed on the PCB on which a connection circuit pattern for electrical connection of the LED devices formed; and the lamp housing accommodating the LED module therein. Each of the LED devices disposed on the LED module is equipped with the dispersion lens having a structural feature for dispersing the light emitted from the LED devices to both sides.

Description

LED light fixture with dispersive lens

The present invention relates to an LED luminaire, and more particularly, to a lamp housing consisting of two objects forming an inclined surface, and an arrangement of LED elements mounted on a PCB of an LED module mounted on the lamp housing and the LED element. It relates to an LED lighting fixture capable of maximizing side illumination through the mounted dispersion lens.

In lighting equipment, in particular, a streetlight means a lighting device installed along a road for lighting of a street, safety of traffic, or aesthetics.

Conventional streetlights mainly use lamps that emit light using the filament resistance, but this has a short lifespan and a lot of power consumption, and in recent years, LED (Light Emitting) has a longer lifespan and higher energy efficiency than the filament type lamp. Diode) as a light source is being developed and applied.

According to the current installation standards for streetlights, when the streetlight is installed at a height of 10m from the ground, the side illumination generated at the point of the ground 10m from the left and right sides of the ground where the lighting equipment is installed should emit light up to 20Lux.

However, in the case of a lighting device composed of LED, the side illumination and visibility are poor due to the characteristic of having straightness in emitting light from the LED. When the LED lighting device is simply configured in the same manner as the conventional filament type lighting device, There is a problem in that the light going to the side is weak, so that the streetlight installation standard, that is, the side illumination 20Lux, is not satisfied.

The present invention has been conceived to solve the above problems, and an object of the present invention is to provide an LED device mounted on a PCB of an LED module accommodated in a lamp housing, and the dispersion of the present invention is mounted to surround each of the LED devices. Through the structural features of the lens, it is to provide an LED lighting fixture capable of satisfying the lighting fixture installation standard by maximizing side illumination while using minimum energy.

An LED lighting device according to the present invention for achieving the above object includes: an LED module in which a plurality of LED elements are disposed on a PCB on which a connection circuit pattern for electrical connection of the LED elements is formed; It includes a lamp housing for accommodating the LED module therein, and each of the LED elements disposed in the LED module is equipped with a dispersion lens for dispersing the light emitted from the LED element to both sides, and the dispersion lens, A medium constituting the interior to refract light emitted from the LED device; A pair of air gaps formed on both sides of the medium in order to reduce the light emitted from the LED element from being excessively refracted and dispersing to an unnecessary lateral direction; And a receiving groove for inserting and receiving the LED element therein, wherein the air gap is composed of a wall surface and an image side surface, and an empty space isolated from the medium filling the interior of the dispersion lens by the wall surface and the image side surface. And the image side surface is configured to be inclined downward from the outer region of the dispersion lens to the region where the LED element is located, and the sectional shape of the dispersion lens in one direction is based on the center of the dispersion lens. It is formed as a convex curved surface, and the cross-sectional shape in a direction perpendicular to the one direction is characterized in that the volume is reduced and narrower as the dispersion lens goes from the top to the bottom.

According to the LED lighting device according to the present invention, the side illumination of the LED lighting device is weak by efficiently dispersing the light emitted from the LED device in both directions through a dispersion lens mounted on each LED device arranged in the LED module. There is a remarkable effect that can solve the problem.

In addition, according to the LED lighting device according to the present invention, in particular, by reducing the light scattered in the lateral direction through the air gap formed in the dispersion lens, and inducing the light to be refracted and dispersed only above an appropriate dispersion angle, There is a remarkable effect that both the side illumination and the overall illumination can achieve brightness that meets more than the lighting fixture installation standard.

1 is an exploded perspective view showing the configuration of an LED lighting fixture according to the present invention.
Figure 2 is an exploded perspective view showing the configuration of the lamp housing of the LED lighting fixture according to the present invention.
3 is a plan view showing the arrangement of the LED module 120 is mounted and accommodated in the lamp housing (100, 110) of the LED lighting fixture according to the present invention.
4 and 5 are an upper perspective view and a lower perspective view of the lamp housings 100 and 110 according to the present invention.
6 and 7 are cross-sectional views in the horizontal and vertical directions of the lamp housings 100 and 110 in which the LED module 120 according to the present invention is mounted.
8 is a perspective view showing a dispersion lens mounted on each LED element of the LED lighting fixture according to the present invention.
9 (a) and (b) are cross-sectional views of a dispersion lens according to the present invention.
10 (a) and (b) are top and bottom views of the dispersion lens according to the present invention.
11 (a) and (b) are side and front views of a dispersion lens according to the present invention.

1 is an exploded perspective view showing the configuration of an LED lighting fixture according to the present invention.

Referring to FIG. 1, the LED lighting fixture according to the present invention basically includes a pair of LED modules 120 in which a plurality of LED elements are disposed on a PCB on which a connection circuit pattern for electrical connection of the LED elements is formed; Two physically separated entities form a pair, each of which is assembled and arranged at an angle from the ground to form a'∨' shape, and the pair of LED modules 120 are installed and accommodated in each Lamp housings 100 and 110; The front bracket 130, the rear bracket 140, and at least two are fastened to each other along the outermost rims of the pair of lamp housings 100 and 110 arranged in the'∨' shape to form an overall rectangular frame. Side brackets 150 and 160; And a support 180 that is coupled to the rear bracket 140 so that the frame formed by mutually fastening the front bracket 130, the rear bracket 140, and the side brackets 150 and 160 can be fixedly disposed on a streetlight pole. ).

Prior to describing the LED lighting fixture according to the present invention, the term'vertical length direction' used hereinafter refers to the long axis direction of the rectangular frame, that is, a direction parallel to the long axis direction of the side bracket, and'horizontal The'length direction' refers to a direction perpendicular to the'vertical length direction'.

The lamp housings 100 and 110 of the LED luminaire according to the present invention have a lamp housing composed of two parts, and the two lamp housings 100 and 110 are mutually formed, unlike a conventional LED illuminator composed of one lamp housing. It forms a predetermined inclination angle and is configured to form a'∨' shape.

The inclination angle is preferably configured such that each of the lamp housings 100 and 110 has an inclination angle of 15° to 17° from the ground.

This is an inclination angle for maximizing side illuminance and visibility that meets the standard for installing streetlights by directing the emitted light to the side in consideration of the characteristic having straightness in emitting light from the LED.

It is preferable to apply any one selected from aluminum or thermally conductive plastic to the lamp housings 100 and 110 so that heat generated from the LED can be smoothly discharged.

The front bracket 130, the rear bracket 140 and the side brackets 150 and 160 according to the present invention are assembled with each other by fastening members such as bolts and nuts, each of which is arranged in the'∨' shape. Along the outermost rims of the housings 100 and 110, they are assembled and connected in a structure covering the rims.

Specifically, the rear bracket 140 is coupled to the support 180, and the side brackets 150 and 160 are bent at both ends in a'L' shape, and one end is fastened to the front bracket 130 and the other end By being fastened to the rear bracket 140, the front bracket 130, the rear bracket 140, and the side brackets 150 and 160 finally form a single frame in a square shape.

In addition, the side brackets 150 and 160 are basically configured such that two side brackets 150 and 160 form the left and right corners of the rectangular frame and are fastened, but at least two side brackets 162 and 164 are provided with the front bracket 130 ) And the rear bracket 140 may be configured to be further fastened over the center of the rear bracket 140 so that the LED lighting device can be more stable and securely protected from external forces such as rain and wind.

In addition, in response to the pair of lamp housings 100 and 110 forming a predetermined inclination angle and being configured in a'∨' shape, the front bracket 130 and the rear bracket 140 also have an overall shape of the lamp housing ( It is preferable to manufacture in a'∨' shape composed of the same inclination angle as the inclination angle formed by 100,110).

This prevents the case where light emitted from the lamp housings 100 and 110 mounted between the front and rear brackets 140 and directed to the side is blocked by the front and rear brackets 140, thereby maximizing the improvement of side illumination. This is to do.

Although not shown in FIG. 1, the LED lighting fixture according to the present invention for improving side illumination allows the pair of lamp housings 100 and 110 to be arranged in a shape opposite to the'∨' shape, that is, a'∧' shape. , The front bracket and side bracket covering the front and rear surfaces of the pair of lamp housings 100 and 110 may also be configured in a'∧' shape formed at the same inclination angle as the inclination angle formed by the'∧' shape.

The LED lighting fixture according to the present invention in which the pair of lamp housings 100 and 110 are arranged in a'∧' shape differs only in the arrangement structure of the'∨' shape LED lighting fixture and the lamp housing, but the remaining components are the same. The'∧'-shaped LED lighting fixture also exhibits an effect of improving side illumination like the'∨'-shaped LED lighting fixture.

When the primary assembly through the fastening of the front and rear brackets 140 and the side brackets 150 and 160 is completed, as described above, the overall shape forms one frame of a square shape, and the inside of the lamp housings 100 and 110 An empty space for mounting is formed.

Thereafter, when the lamp housings 100 and 110 are inserted and mounted in the empty space inside the frame, the secondary assembly is completed.

As described above, the first assembly to complete one frame through fastening between the front bracket 130, the rear bracket 140, the side brackets 150, 160, and the support 180, and a pair of lamp housings on the frame When the secondary assembly of inserting and mounting (100, 110) is completed, a current converter (eg, inverter or SMPS; 230) is installed on the upper side of the lamp housing (100, 110).

The current converter 230 is formed so that a rod-shaped fixing bar 145 protrudes on an inner surface of the rear bracket 140 (a surface facing one surface of the front bracket 130), and the front bracket The lamp housing is configured to be supported by the support bar 250 by attaching and fixing the current converter 230 to the fixing bar 145 by attaching a rod-shaped support bar 250 to 130. It can be stably installed on the upper side of (100,110).

The current converter 230 converts the voltage input from the power to the required voltage and then rectifies it again and supplies it to the LED module 120 accommodated in the lamp housings 100 and 110 so that the LED light source is turned on to emit light. To do it.

The secondary assembly allows the pair of lamp housings 100 and 110 to form a predetermined inclination angle and be coupled to the front and rear brackets 140 through the following structural features, and specific lamp housings 100 and 110 The bay can be separated/coupled very easily from the front and rear brackets 140, so that the installation, repair, and replacement of the LED lighting equipment can be conveniently performed.

A pair of locking plates 170, 172, 174 and 176 are mounted on the inner side of the front bracket 130 and the inner side of the rear bracket 140 opposite to the inner side according to the present invention.

Accordingly, a plurality of through holes for fastening the plurality of locking plates 170, 172, 174, 176 are formed in the front bracket 130 and the rear bracket 140, respectively, and the fixing screw bolts pass through the through holes to pass the stiffening plate. By screwing into the fastening hole formed in the plurality of locking plates 170, 172, 174, 176 may be coupled and fixed to the front bracket 130 and the rear bracket 140, respectively.

In addition, the predetermined inclination angle formed by the lamp housings 100 and 110 according to the present invention is determined by the inclination of the locking plates 170, 172, 174 and 176 to which the lamp housings 100 and 110 are fitted.

Therefore, the through hole is formed so that the locking plates 170, 172, 174, 176 form a predetermined inclination angle (preferably, forming an inclination angle of 15° to 17° from the ground) and be fastened to the front and rear brackets 140. ·It must be formed in the proper position of the rear bracket 140.

In addition, at least two locking grooves 171 are formed in the locking plates 170, 172, 174, 176, and the number of locking protrusions equal to the number of locking grooves 171 are formed on both end surfaces of the lamp housings 100 and 110. 117) is protruding.

The locking protrusion 117 is guided by the locking groove 171 and slides to the end of the locking groove 171 so that the lamp housings 100 and 110 can be engaged with the locking plates 170,172,174,176. .

Specifically, the locking groove 171 is formed in a'b' shape, and the lower end portion of the'a' character of the locking groove 171 is the locking protrusion 117 to be inserted into the locking groove 171 The upper end of the'b' shape to which the locking protrusion 117 is finally engaged is configured to be recessed in the lower direction (ground direction), and

The woojing (100, 110) was to be able to stably maintain a state that is fixed to the locking plate (170, 172, 174, 176).

2 is an exploded perspective view showing the configuration of a lamp housing of an LED lighting fixture according to the present invention.

Referring to Figure 2, the lamp housing according to the present invention (100, 110) comprises a base consisting of a flat surface to which the LED module 120 is attached; A plurality of parallel heat sinks 111 extending upward from the upper surface of the base; Receiving walls 113 formed perpendicular to the corners of both sides of the base; End covers (115a, 115b) coupled to both open surfaces of the lamp housings (100, 110) that are open because the receiving wall (113) is not formed; And a protective plate 190 for protecting the LED module 120 from an external environment by closing one open surface of the lamp housings 100 and 110.

In addition, a connector hole is formed at the end of the base, and a connector 260 is mounted in the connector hole so that current supplied from the outside is attached to the inside of the base through the connector (Fig. 5; 260). ) To be delivered.

In addition, in order to prevent damage from occurring when excessive current is supplied to the LED module 120, a driver 240 for controlling an input current is further included between the connector and the LED module 120. It is desirable.

The end covers 115a, 115b have at least two locking protrusions 117 protruding on one surface thereof, so that the locking protrusion 117 guides the locking groove 171 formed in the locking plates 170, 172, 174, 176. It is configured to be supported and fixed inside the locking plates 170,172,174,176.

The protection plate 190 is stably coupled to the lamp housings 100 and 110 through tightening of screw bolts using the fixing rod 200 to protect the LED module 120 from external dust, snow or rain. do.

The protective plate 190 may be made of a transparent plastic or glass material, and when the protective plate 190 is installed, a rubber gasket 210 having the same shape as the protective plate 190 (i.e., rectangular) is disposed to prevent external moisture. Can be prevented from seeping into the lamp housings 100 and 110.

The LED module 120 is configured by placing a plurality of LED elements on a metal (eg, aluminum) printed circuit board (PCB) on which a connection circuit pattern for electrical connection of a plurality of LED elements is formed, and the metal PCB is It is attached and fixed to the bases of the lamp housings 100 and 110.

3 is a plan view showing the arrangement of the LED modules mounted on a pair of lamp housings of the LED lighting fixture according to the present invention, Figures 4 and 5 are an upper perspective view and a lower perspective view of the lamp housing according to the present invention, 6 and 7 are cross-sectional views in the horizontal and vertical directions of a pair of lamp housings in which the LED module according to the present invention is mounted.

In the following, with reference to FIGS. 3 to 7, the structural features of the LED module 120 and the heat sink 111 extending on one surface of the lamp housing 100 and 110 are mounted and accommodated in the lamp housing 100 and 110 according to the present invention. It will be described in detail.

The LED module 120 mounted and accommodated in the lamp housings 100 and 110 according to the present invention is formed on a metal (eg, aluminum) printed circuit board (PCB) on which a connection circuit pattern for electrical connection of a plurality of LED elements is formed. A plurality of LED elements are arranged in a row along the longitudinal direction of the lamp housings 100 and 110, and the LED elements arranged in a row form a plurality of rows parallel to each other and constitute one LED module 120 do.

The LED module 120 according to the present invention has the following structural characteristics in the arrangement of the LED elements and forms a plurality of rows.

Referring to FIG. 3, a plurality of LED elements are combined and arranged in a row in each of the LED rows, and by giving different density of the arrayed LED elements for each row, the minimum electrical energy consumption (i.e., used LEDs While minimizing the number of elements), the side illumination and visibility were maximized to provide an LED lighting fixture that satisfies the standard for street lighting installation.

Specifically, the LED module 120 according to the present invention is configured such that the LED elements form three columns. In the three LED rows, the LED row located at the innermost side (that is, the central axis region in the vertical direction of the square frame) has a smaller density of LED elements than the remaining two LED rows (i.e., with fewer LED elements. The innermost, that is, constitutes an LED row), is configured to form an empty space between the LED elements, and the corresponding LED row is configured to form an LED row with the LED elements more densely concentrated as it goes outward than the innermost LED row.

That is, in the horizontal direction arrangement of the plurality of LED rows in the lamp housing, a larger number of LED elements are arranged in the corresponding LED row as it goes from the innermost to the outermost side of the lamp housing.

This, in consideration of the characteristics of LED lighting fixtures that are vulnerable to side illumination and visibility, enhances the LED light source arranged near the side and reduces the LED light source arranged in the center area of the streetlight pole, thereby improving the side illumination and the road side illumination. At the same time, LED light is illuminated more than necessary in the central area of the streetlight pole, preventing unnecessary consumption of electrical energy.

This is to prevent.

In addition, looking at one LED row among the plurality of LED rows provided in the lamp housing, in the vertical direction LED element arrangement of the one LED row, from one end of the LED row to the other end (that is, away from the front column of the street light) As it fades), the LED elements were arranged so that the density of the LED elements arranged in the LED row gradually increased.

This is, taking into account the fact that the light of the LED luminaire becomes weaker as the distance from the streetlight pole (that is, toward the road), the more LED elements are arranged as the distance from the pole where the LED luminaire is installed. This is to further improve the side illuminance.

A plurality of heat sinks 111 extending on one surface of the lamp housings 100 and 110 according to the present invention are a means for rapidly discharging heat generated from the LED module 120 to the outside. The sink 111 allows heat dissipation to be performed more efficiently through the following structural features.

The LED module 120 is mounted and accommodated in the lamp housings 100 and 110 according to the present invention, as described above, a plurality of LED rows are arranged in parallel with each other.

Looking at the heat distribution inside the lamp housings 100 and 110 in which the LED module 120 having the above arrangement structure is mounted, a relatively larger amount of heat is detected in the LED column located in the middle than the LED column located on both sides.

Therefore, the heat sink 111 according to the present invention is the lamp housing 100 and 110 among a plurality of parallel heat sinks 111 extending upward from the upper surface of the lamp housing 100 and 110 in consideration of the heat distribution as described above. The heat sinks 111a, 111b, and 111c formed in the central region of the lamp housings 100 and 110 are configured to have a longer height than the heat sinks formed in the outer regions of the lamp housings 100 and 110.

That is, the heat sinks 111a, 111b, and 111c formed longer in the central region can radiate a greater amount of heat per unit time by increasing the contact area with the atmosphere. Accordingly, the heat formed on the central axis It is possible to rapidly dissipate the heat generated relatively more from the LED row located in the middle corresponding to the position of the sinks 111a, 111b, 111c.

8 is a perspective view showing a dispersion lens mounted on each LED element of the LED lighting fixture according to the present invention, Figures 9 (a), (b) are cross-sectional views of the dispersion lens according to the present invention, Figure 10 (a) , (b) is an upper and lower side view of a dispersion lens according to the present invention, and Figs. 11 (a) and (b) are side and front views of the dispersion lens according to the present invention.

The LED lighting device according to the present invention is configured to form an inclination angle in a'∨' or'∧' shape of a pair of lamp housings 100 and 110 composed of two objects, and each of the LED elements constituting the LED module 120 By mounting the dispersion lens 300 having the following structural features to maximize the improvement of the side illumination of the LED lighting fixture.

The angle of inclination is such that each of the lamp housings 100 and 110 is inclined by 15° to 17° from the ground in consideration of the characteristic having straightness in emitting light as described above, so that the emitted light is This is to realize the side illumination that meets the lighting fixture installation standards by dispersing it to the side.

However, only configuring the lamp housings 100 and 110 to be inclined at a certain angle as described above has a limitation in improving side illumination.

For example, in the case of an LED lighting fixture in which the lamp housing is arranged in a'∨' shape, if the inclination angle is less than 15°, the side distance through which the light of the LED light can be transmitted is narrowed, resulting in a decrease in side illumination. If it is formed above 17°, the side distance that can send the light far widens, but due to excessive dispersion of light, the illuminance and visibility in the vertical direction decrease, making it unsuitable for installation standards.

Accordingly, the LED lighting device according to the present invention uses a dispersion lens 300 to overcome the limitation of improving side illumination by a pair of lamp housings 100 and 110 forming an inclined surface in a'∨' (or'∧') shape. By further providing it, the side illumination can be further improved, and the illumination in the vertical direction can also satisfy an appropriate standard value.

Referring to Figures 8 to 11, the dispersion lens 300 according to the present invention is composed of a structure that accommodates and surrounds one LED element 125, specifically, light emitted from the LED element Dispersing units (320, 330) for refracting and dispersing in both directions; LED element receiving groove 350 for inserting the LED element therein; Air gaps (340a, 340b) for preventing the light emitted from the LED element from being excessively distributed to the side; It is configured to include a coupling plate 360 for assembling and fixing the dispersion lens 300 to the LED module.

In more detail, the interior of the dispersion lens 300 according to the present invention is a solid material made of a transparent plastic material constituting the dispersion lens 300 except for the air gaps 340a and 340b and the receiving groove 350 That is, since it is composed of the medium 305, the light emitted from the LED element passes through the medium 305, is refracted, and is radiated to the outside of the lens.

The dispersion lens 300 according to the present invention is configured to have the following structural characteristics in order to induce the light emitted from the LED device to be linearly distributed to both sides.

1) The cross-sectional shape of the dispersion lens 300 according to the present invention in the transverse direction is as shown in FIG. 9 (a), and both left and right sides divided by the center 310 of the dispersion lens 300 Each of the (320,330; hereinafter dispersion units) is configured to have a convex curved surface.

By the dispersion lens 300 having the convex curved dispersing units 320 and 330 formed as described above, the light emitted from the LED element 125 is refracted through the dispersing units 320 and 330 and diffused in both directions so that irradiation is performed. By doing so, the LED light is not concentrated in the vertical direction and can be more effectively dispersed in the lateral direction, thereby improving the side illumination of the LED lighting fixture.

In addition, the cross-sectional shape in the longitudinal direction of the dispersion lens 300 according to the present invention, as shown in Figure 9 (b), the volume of the dispersion lens 300 is reduced and narrowed as it goes from the top to the bottom. By configuring it in a spiral shape, the light that is excessively refracted in the lateral direction (l) by the internal medium 305 of the dispersion lens 300 is guided in the front direction (m), and as a result, the optimal dispersion direction (n ) To be radiated.

Accordingly, it is possible to prevent a problem in that the light emitted from the LED element 125 is excessively distributed in the lateral direction than necessary, so that both the front illumination as well as the side illumination may be lowered.

As described above, the dispersion lens 300 according to the present invention has a straightness through the body structure formed in the shape of a bare foot and the dispersion portions 320 and 330 formed on both left and right sides, and the light emitted from the LED element 125 is not excessive. By inducing them to be efficiently distributed to the sides without being insufficient, it enables optimal visibility that meets the installation standard of lighting equipment (ie, street lights).

2) When the LED light is excessively dispersed in all directions through the dispersing unit and the barbed body of the dispersion lens 300 according to the present invention, the side illumination can be improved, but the overall illumination of the LED lighting equipment will be reduced. A possible problem occurs.

Accordingly, the dispersion lens 300 according to the present invention has a pair of air gaps on both sides of the internal medium of the dispersion lens 300 in order to prevent the problem that the overall illumination decreases as much as the side illumination is improved as described above. (340a, 340b) were formed.

That is, in the dispersion lens 300 of the present invention, a pair of air gaps 340a and 340b are formed in a shape symmetrical to the left and right sides of the receiving groove 350 provided for inserting and receiving the LED element.

The air gaps 340a and 340b are a pair of empty spaces formed on both sides of the inner medium of the dispersion lens 300, and the empty spaces are filled with air. The air gaps 340a and 340b are excessively refracted by the internal medium of the dispersion lens 300 to reduce light scattered to the lateral direction (Fig. 9(b); l) where illumination is unnecessary, and a proper dispersion angle ( By increasing the scattered light that is refracted by 25° or more from the bottom of the dispersion lens 300), it is possible to efficiently improve the overall illuminance as well as the side illuminance.

Specifically, the air gaps 340a and 340b are composed of a wall surface 341 and an upper surface 343, and a medium 305 constituting the interior of the dispersion lens by the wall surface 341 and the image side surface 343 ), and the image-side surface 343 is configured to incline downward from the outer region of the dispersion lens 300 to the region where the LED element is located.

The configuration of the image side to be inclined is to reduce light that is excessively refracted and directed toward the side that does not require illumination, while the light is refracted by more than an appropriate dispersion angle so that the diffused light is transmitted to the outside of the dispersion lens 300 and radiated. It is to induce.

The degree of inclination formed by the image side surface is structurally configured so that the angle formed by the extension lines of the image side surfaces of the air gaps 340a and 340b respectively formed on both sides of the dispersion lens 300 meets 110° to 130° It is desirable to do.

3) Referring to Figure 10 (a), the dispersion lens 300 according to the present invention in the shape of a cross-section parallel to the bottom surface of the dispersion lens 300, a cross-section parallel to the bottom surface of the dispersion lens 300 Looking at the shape of, both side surfaces 303 and 304 facing each other are configured as concave curved surfaces, and the other two side surfaces 301 and 302 perpendicular to the both side surfaces are configured as convex curved surfaces.

This is to induce the light refracted through the inner medium 305 of the dispersion lens 300 to pass through the curved surfaces 301, 302, 303, and 304 and spread in all directions, thereby improving side illumination and realizing a uniform side illumination as a whole. It is to do.

In addition, the receiving groove 350 is formed in the center region of the inner medium of the dispersion lens 300 in the same shape as the LED element and a size sufficient to accommodate the LED element.

According to the specific experimental results, in the case of lighting by an LED element without the dispersion lens 300 according to the present invention, the side illumination and visibility satisfying the installation criteria for lighting equipment (street lamps) are limited to around 60°, but the above In the case of the LED element 125 equipped with the dispersion lens 300, the side surface of the light is refracted and diffused through the dispersion units 320 and 330.

It was confirmed that the range of illuminance and visibility was increased to 120°.

That is, the LED lighting fixture according to the present invention is configured to form an inclined surface while the two lamp housings 100 and 110 form a'∨' (or'∧') shape as described above, and each provided in the LED module 120 By attaching a barbal-shaped dispersion lens 300 in which the left and right dispersion portions 320 and 330 are formed on the LED element, the problems of the conventional LED lighting equipment vulnerable to side illumination have been improved.

In particular, the dispersion lens 300 of the present invention reduces the light dispersed to the side direction through the air gaps 340a and 340b formed in the dispersion lens 300, and the light is refracted and dispersed above an appropriate dispersion angle. By inducing it to be radiated, both the side illumination and the overall illumination can achieve brightness that meets the installation standard of lighting equipment (street lamps).

Although preferred embodiments of the present invention have been described and illustrated using specific terms above, such terms are only for description of the present invention, and are variously modified by those skilled in the art within the scope not departing from the technical spirit of the present invention. It is obvious that it is likely to be implemented.

These modified embodiments should not be individually understood from the spirit and scope of the present invention, but should be said to fall within the scope of the claims appended to the present invention.

100, 110: lamp housing
111: heat sink
115a, 115b: end cover
125: LED element
117: stumbling block
120, 121: LED module
130: front bracket
140: rear bracket
145: fixed bar
150,160,162,164: side bracket
171: locking groove
170,172,174,176: stop plate
180: support
190: protective plate
200: fixed stick
210: rubber gasket
230: current converter
240: driver
250: support bar
260: connector
300: dispersion lens
320,330: dispersion unit
340a, 340b: air gap
350: LED device receiving groove
360: bonding plate

Claims (8)

As an LED lighting fixture,
An LED module in which a plurality of LED elements are disposed on a PCB on which a connection circuit pattern for electrical connection of the LED elements is formed;
Includes a lamp housing accommodating the LED module therein,
Each of the LED elements disposed in the LED module includes a receiving groove for inserting and receiving the LED element in order to prevent the light emitted from the LED element from being refracted and dispersed more than necessary, and the left side of the receiving groove An LED lighting device, characterized in that a dispersion lens having an air gap provided in a shape symmetrical to the right is mounted. The method of claim 1,
The air gap is composed of a wall surface and an image side surface to form an empty space separated from the medium constituting the interior of the dispersion lens by the wall surface and the image side surface,
The image side surface of the LED lighting device, characterized in that it is configured to incline downward toward the area where the LED element is located from the outside of the dispersion lens. The method of claim 1,
The cross-sectional shape of the dispersion lens in one direction is formed with a convex curved surface on both left and right sides of the center of the dispersion lens, and the cross-sectional shape in a direction perpendicular to the one direction decreases from the top to the bottom of the dispersion lens. LED lighting fixture, characterized in that consisting of a narrowing and narrowing spiral shape. The method of claim 2,
The inclination angle of the upper side is,
An LED lighting device, characterized in that the angle formed by the intersection of the extension lines of the image side of the air gap formed on both side portions of the dispersion lens is 110° to 130°. The method of claim 1,
The shape of the cross section parallel to the bottom surface of the dispersion lens,
Both sides facing each other are composed of concave curved surfaces,
LED lighting fixtures, characterized in that the other two sides perpendicular to the two side surfaces are formed of a convex curved surface. The method of claim 2,
LED lighting fixture, characterized in that the medium constituting the interior of the dispersion lens is made of a transparent plastic material. In the LED lighting equipment using LED lighting light,
An LED module in which a plurality of LED elements are disposed on a PCB on which a connection circuit pattern is formed;
A plurality of lamp housings that are physically separated into at least two, and in which the LED modules are respectively accommodated; And
A front bracket, a rear bracket, and at least two side brackets are coupled to each other along the outermost rims of the plurality of lamp housings to form an overall rectangular frame,
The lamp housing includes a base composed of a flat surface to which the LED module is attached and received;
A plurality of parallel heat sinks extending upward from the upper surface of the base;
A receiving wall extending at both corners of the base;
An end cover coupled to both side open surfaces of the lamp housing which is open because the receiving wall is not formed;
At least two locking protrusions protruding from one surface of the end cover; And
It is configured to include a protective plate for protecting the LED module from an external environment by closing one open surface of the lamp housing,
On the inner surfaces of the front bracket and the rear bracket, a plurality of locking plates having at least two locking grooves for guiding locking by guiding the locking protrusion protruding from the end cover are mounted,
A plurality of through holes are disposed through the front bracket and the rear bracket, so that the locking plate is mounted to the front bracket and rear bracket through the screw bolt and the through hole, and a slope is given,
The lamp housing coupled to the locking plate is assembled and disposed to be inclined from the ground by an inclination formed by the locking plate, so that the plurality of lamp housings have a'∧' shape as a whole. The method of claim 7,
The locking groove is formed in a'b' shape, the lower end of the'a' shape of the locking groove is formed to be open so that the locking protrusion is inserted into the locking groove, and the locking protrusion is finally engaged 'LED lighting equipment, characterized in that the upper end of the ruler is configured to be recessed in the direction of the ground.

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