KR102210147B1 - A reclamation type signal lamp of the ground - Google Patents

Abstract

The present invention relates to a floor-type pedestrian traffic light which is basically installed between a curb (boundary) of a crosswalk and a sidewalk (or induction block for a blind person). Specifically, the present invention relates to the floor-type pedestrian traffic light wherein an LED module is installed to be inclined in a sidewalk direction, and a lens for refracting an emitted light of an LED to be more inclined in the sidewalk direction is installed at the same time. Therefore, the emitted light is irradiated to be closer to a pedestrian and farther from a driver than that of an existing emitted light when the crosswalk and the sidewalk are installed at an ideal place which is a flatland, and the emitted light is at least irradiated close to the pedestrian by a lens even when the sidewalk is installed in an inclined normal place with respect to the crosswalk.

Description

A reclamation type signal lamp of the ground}

The present invention relates to a floor-type pedestrian signal light in principle that is installed between the curb (border seat) of a crosswalk and the sidewalk (or guidance block for the disabled).In particular, the LED module is installed inclined in the sidewalk direction and the LED Lenses that refract the exit light more inclined toward the sidewalk are installed, and when installed in an ideal place where the pedestrian crossing and sidewalk are flat, the light is radiated closer to the pedestrian and farther away from the driver than the existing exit light, and the pedestrian crossing is guided. It relates to a floor-type pedestrian traffic light that allows the emitted light to be irradiated closer to the pedestrian side by at least a lens even if it is installed in a normal place inclined.

In general, crosswalks allow a vehicle to safely cross a road, and are mainly provided at intersections of roads or other places where there are many road crossings.

In such a crosswalk, a crosswalk traffic light that can periodically display a stop signal and a crossing signal is usually installed, and the crosswalk traffic light is installed at a certain height from the floor surface through a post.

The crosswalk traffic lights are installed according to the pedestrian's eye level, but since the signal can be checked only when the head is raised, for example, a pedestrian who uses a mobile phone with his head lowered frequently does not recognize the change of the signal quickly. In this case, accidents frequently occur in which pedestrians cannot cross even though the crossing signal is crossing or collide with a vehicle while urgently crossing by recognizing the crossing signal late.

In order to solve the above problems, recently, a floor-type walking signal light auxiliary device that is controlled interlocking with the crosswalk traffic lights has been buried in the floor of the crosswalk so that pedestrians who are bowing their heads can clearly and quickly recognize changes in the signals of the traffic lights. The conventional floor-type walking signal light auxiliary device is buried in the inclined ground at both ends of the crosswalk as shown in Fig. 1(b), so that the pedestrian waiting for the traffic light cannot easily identify the floor type walking signal light auxiliary device. Conversely, the driver of the vehicle can easily identify the auxiliary device for the pedestrian traffic light, and the driver of the vehicle can drive safely due to the contrary signal light between the traffic light and the auxiliary device for the floor type walking signal. There was an obstructive problem.

A conventional floor-type pedestrian traffic light for solving this problem is proposed, for example, known in Patent Document 1 (Korean Patent No. 10-2100443).

Referring to FIG. 8 (corresponding to FIG. 4A of Patent Document 1), the upper portion of the support member 20 supporting the PCB substrate 10 is formed to be inclined to induce the PCB substrate 10 to be inclined at a predetermined angle, Pedestrians waiting for a traffic light can easily identify the light emitted from the PCB board 10 to effectively observe the walking signal, and at the same time, the driver can induce safe driving because it is difficult to identify the light emitted from the PCB board 10 There is an effect that can be done.

The inclination of the PCB board 10 must be designed to be inclined 10 degrees in the direction of the sidewalk according to the standard guidelines for auxiliary devices for floor-type pedestrian traffic lights passed deliberation by the National Police Agency in March 2019.

This inclination is effective when the curb and the sidewalk of the crosswalk is an ideal horizontal level as shown in FIG. 1(a).

However, since it is a normal downhill from the sidewalk to the curb of the crosswalk as shown in Fig. 1(b), the 10 degree slope of the PCB board 10 is canceled according to the slope of the downhill, so that the light does not go toward the pedestrian but is vertical or toward the roadway. It will shine.

Accordingly, pedestrians go closer to the roadway and stop, so that they are exposed to traffic accidents more severely, and drivers are affected by not only the lights of the other vehicle but also the lights of the floor-type walking lights, and thus, the safety driving is hindered by severe glare.

On the other hand, it is known in the publication of Patent Document 2 (Korean Patent No. 10-2108789) in which the LED module 25 is placed horizontally without inclining in the direction of guidance.

As shown in Fig. 9 (corresponding to Fig. 7 of Patent Literature 2), the bottom traffic light of Patent Document 2 has an inclined surface B1 extending in the longitudinal direction of the floor traffic light on the upper surface of the upper case 27 made of plastic. By providing a top lens that is one-dimensionally arranged in the width direction of the floor traffic light, light having an angle S1 inclined by the reflector 261 is further inclined in the guiding direction by additionally having a refraction angle S2 by the top lens. Lose.

The upper surface of the upper case 27 constitutes a top lens (B1) having a comb-tooth pattern extending in the longitudinal direction while being serrated in cross-section, and the light incident by the top lens (B1) is slightly in the guiding direction, for example 10 The degree of refraction is performed, and the top lens B1 also has an effect of preventing the pedestrian from sliding. And optionally, a bottom lens B2 in which embossed convex portions B2 are two-dimensionally arranged may be provided on an inner surface opposite to the upper surface of the upper case 27.

However, in Patent Document 2, as the LED module 25 is installed horizontally, a component of the reflector 26 is added, and the structure according to the installation is complicated.

In addition, in Patent Document 2, the top lens (B1) is formed on the upper surface of the upper case (27) and has a role of refracting, as well as the anti-slip effect of pedestrians, but the top lens (B1) is used by the passage of a number of pedestrians or moving means. If a slight change in shape of the top lens (B1) occurs during wear while stepping on, it is not possible to secure a path of light for pedestrians.

In addition, since the space between the bottom lens B2 and the LED module 25 is wide, the air in the space becomes a volume space according to a temperature change, and there is a very high risk of condensation.

In addition, since the upper case 27 is supported by the lower case 21 only with its rim, the upper case 27 has a pressure such as vibration resistance and impact resistance that is continuously applied by a person stepping on it or by placing a wheel of the vehicle. The inside of the width direction is bent downward, so that the durability is remarkably deteriorated or the waterproof and dustproof effect is lost due to cracks.

Korean Patent Registration No. 10-2100443 Korean Patent Registration No. 10-2108789

The present invention was devised to solve the above-described problem, and even if it is installed on an ideal flat ground or on a normal slope, it satisfies the standard guidelines of an auxiliary device such as a floor-type walking signal, while inducing the pedestrian to be as far as possible from the roadway, and to the driver Its purpose is to provide a floor-type pedestrian traffic light that contributes to a safe traffic culture by not disturbing traffic.

In order to achieve the above object, a floor-type pedestrian traffic light according to the present invention includes: a housing including a transparent upper housing and a lower housing; An LED module including a PCB installed to be inclined to the right (in the direction of India) in the lower housing and an LED mounted on the PCB; Including a lens integrally molded on the lower surface of the upper housing, wherein the lens has a left and right asymmetrical parabolic shape convex downward with respect to the vertical optical axis (z) of the LED, and a recess in which the LED is placed is formed at a vertex of the lens. , It is left and right asymmetric with respect to the vertical optical axis (z), and the groove includes an image inner refractive wall and a left and right inner refractive wall to which light from the LED is incident and refracted, and the image inner refractive wall is the vertical optical axis (z) It is divided into a first image inner refractive wall formed on the left side with a curved surface convex downward around the center, and a second image inner refractive wall formed on the right side with a flat surface parallel to the same inclination as the PCB. The inner refractive wall is disposed so that the 1a, 1b inclination angles θ1a and θ1b in the direction opening downward with respect to the vertical optical axis z are θ1a <θ1b, and the left and right outer reflective walls of the lens are the vertical optical axis z The 2a and 2b inclination angles (φ2a) (φ2b) in the upward opening direction are arranged such that φ2a <φ2b.

In addition, in the floor-type walking traffic light according to the present invention, the lens is formed with a long axis along the horizontal direction of the upper housing, the long axis lens is installed at predetermined intervals along the vertical direction of the upper housing, and the lower In the housing, a column protruding is formed between the long axis lenses to support the lower surface of the upper housing.

Moreover, in the floor-type walking traffic light according to the present invention, a first coupling protrusion and a first coupling groove are formed on a bottom surface of the upper housing and an upper surface of the lower housing, which are in contact with each other, and injected into the upper outside of the first coupling groove. A first overflow allowable groove is formed to allow the overflow of silicon, and an additional pillar further supporting the lower surface of the upper housing is formed on the rim of the lower housing, and the lower surface of the upper housing and the additional pillar are formed. A second coupling protrusion and a second coupling groove are formed on the upper surface, and a second overflow allowable groove is formed on the upper outside of the second coupling groove to allow overflow of the injected silicon, and the first coupling protrusion and the first coupling The groove is disposed outside and below the second coupling protrusion and the second coupling groove.

In addition, in the floor-type walking traffic light according to the present invention, an anti-slip protrusion is integrally formed on the upper surface of the upper housing.

According to the present invention, there are the following effects.

The LED module is first inclined in the direction of the sidewalk, which is the opposite direction to the roadway (satisfying the standard guidelines), and the light emitted from the first tilted state is secondly refracted through the lens, and is emitted to the vehicle when the ground is embedded in the flat sidewalk. Instead of drastically reducing the amount of light generated, more light is emitted toward the sidewalk, minimizing the interference of light to the driver of the vehicle and increasing the light to pedestrians. Accordingly, it greatly contributes to a safe traffic culture by further improving the visibility of pedestrians while reducing driver's driving obstruction and further increasing the distance from the roadway.

In particular, the first image inner refracting wall formed on the left side with a curved surface convex downward around the vertical optical axis z, and the second image inner refractive wall formed on the right side with a parallel flat surface at the same inclination as the LED module. At the same time, the left and right inner refractive walls of the lens are arranged such that the 1a, 1b inclination angles (θ1a) (θ1b) in the direction opening downward with respect to the vertical optical axis (z) of the LED are θ1a <θ1b, and the left and right outer reflective walls of the lens Is arranged so that the 2a, 2b inclination angles (φ2a) (φ2b) in the upward opening direction with respect to the vertical optical axis (z) are φ2a <φ2b, so that the left and right light emitted from the LED module inclined in the guiding direction is vertical optical axis (Z). It does not collect on the bed and is discharged more inclined toward the direction of delivery.

Of course, even if the ground is buried in an inclined sidewalk, even if at least the primary refraction is offset by the inclined ground, it satisfies the standard guidelines that at least the secondary refraction should be designed to be inclined 10 degrees in the direction of the sidewalk like the primary refraction.

In addition, since the lens is disposed in the space where the LED module is mounted, the space is narrowed by the volume occupied by the lens, and the air (volume space) in the narrow space is also minimized to prevent condensation due to temperature changes.

In addition, since the upper housing is supported by the upper housing between the lens and the lens in the width direction, durability can be remarkably improved by withstanding earthquake resistance and impact resistance much better.

In addition, since the lens is integrally formed with a long long axis along the horizontal direction, it is very excellent to implement a layout such as the spacing or number of LEDs according to the installation position of the floor-type walking signal light.

In addition, the coupling protrusion of the upper and lower housings, the coupling groove, and the overflow allowable groove are combined with the double waterproof and dustproof structure, so that the coupling protrusion of the upper housing squeezes the silicon of the coupling groove and the remaining space due to the overflow phenomenon of the silicon generated by compression. By removing the air layer in the air, it fills the gaps to form a perfect double waterproof and dustproof structure.

Figure 1 is a floor-type pedestrian traffic light (a) an ideal roadway sidewalks on a flat ground, (b) an open road installed between an inclined conventional roadway sidewalk.
Figure 2 is a perspective view showing a floor-type walking traffic light according to a preferred embodiment of the present invention.
3 is an exploded perspective view of an upper housing and a lower housing of FIG. 2;
4 and 5 are cross-sectional views taken along lines 4-4 and 5-5 of FIG. 2;
6 is a cross-sectional view for explaining only the lens of the present invention.
7 is a cross-sectional view showing the incident / reflection / refraction of the light of the LED module of the present invention to the lens.
Figure 8 is a state of use of a conventional floor-type walking signal auxiliary device.
9 is a diagram schematically showing a state of reflection and refraction of light in a cross-sectional width direction of another conventional floor traffic lamp.

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

2 is a perspective view showing a floor-type pedestrian traffic light according to a preferred embodiment of the present invention, FIG. 3 is an exploded perspective view of the upper housing and the lower housing of FIG. 2, and FIGS. 4 and 5 are 4-4 and FIG. It is a cross-sectional view taken along line 5-5, FIG. 6 is a cross-sectional view for explaining only the lens of the present invention, and FIG. 7 is a cross-sectional view showing incident/reflection/refraction of light from the LED module of the present invention to the lens.

Floor type walking traffic light 1 according to an embodiment of the present invention, as shown in Figs. 2 to 5, the housing 100 forming the outer shape, the LED module 300 and the lens mounted inside the housing 100 Includes 500.

The housing 100 includes an upper housing 110 and a lower housing 130 that are fastly coupled to each other, as shown in FIG. 3.

The upper housing 110 serves as a cover for opening and closing the upper surface of the lower housing 130.

The upper housing 110 and the lower housing 130 are formed of a plastic material. In particular, the upper housing 110 is formed of a transparent PC (polycarbonate) material to emit light.

The LED module 300 is mounted on the inner floor of the lower housing 130.

The LED module 300 includes a PCB 310 and an LED 330 mounted on the PCB 310.

The PCB 310 is installed on the inclined floor 131 inclined about 10° in the direction of guidance (right direction) on the inner floor of the lower housing 130, and satisfies the standard guidelines for auxiliary neglect of floor-type walking traffic lights (the National Police Agency).

The LED 330 is RED and GREEN, and interlocks with the pedestrian traffic light to illuminate the color to the pedestrian.

The lens 500 is integrally protruded downward from the lower surface 113 of the upper housing 110 along the horizontal direction (long axis), and the lens 500 is also installed to be inclined by 10° in the guiding direction like the PCB 310 Has been.

That is, the lens 500 has a left and right asymmetrical parabolic shape convex downward with respect to the vertical optical axis z of the LED 330, that is, the left and right outer reflective walls 517 and 519, as shown in FIGS. It has a parabolic shape. At this time, the upper surface 111 of the upper housing 110 becomes an emission surface of light.

In addition, a recess 510 in which the LED 330 is placed is formed at the vertex of the lens 500.

The groove 510 is also left and right asymmetric with respect to the vertical optical axis z.

That is, the groove 510 includes an image inner refractive wall 511 and left and right inner refractive walls 513 and 515 through which light from the LED 330 is incident and refracted.

The image inner refracting wall 511 has a first image inner refracting wall 511a formed on the left side with a curved surface convex downward around the vertical optical axis z, and a flat surface parallel to the same inclination as the PCB 310. The second image-inside refractive wall 511b formed on the right side is divided into left and right asymmetrically.

In particular, the first image inner refractive wall 511a is a convex lens type whose thickness gradually increases toward the vertical optical axis z at a point where it meets the left inner refractive wall 513.

In addition, the second image-inside refractive wall 511b is a flat incident refractive surface having the same inclination as the PCB 310 at a point where it meets the right-inner refractive wall 515.

First of all, when incident, refraction, reflection, and emission from the left and right of the inclined vertical optical axis z converge, the following conditions must be satisfied in order to allow the light to spread in the guiding (right) direction without canceling the light.

Like the PCB 310, the inclined vertical optical axis z refers to a central axis inclined 10 degrees in the guiding direction.

The left and right outer reflective walls 517 and 519 are totally reflected.

The left and right inner refractive walls 513 and 515 of the lens 500 are disposed such that the 1a, 1b inclination angles θ1a and θ1b in the direction opening downward with respect to the vertical optical axis z are θ1a <θ1b, and the lens 500 The left and right outer reflective walls 517 and 519 of) should be arranged such that the 2a, 2b inclination angles φ2a (φ2b) in the upward opening direction with respect to the vertical optical axis z are φ2a <φ2b.

Due to such an inclination angle, as shown in FIG. 7, when installed on an ideal flat surface, light is irradiated at an inclination of 14° or more toward a pedestrian, and when installed on a normal slope, light is irradiated at an inclination of about 10° toward a pedestrian. .

On the other hand, as shown in Figure 2, the upper surface 111 of the upper housing 110, the non-slip protrusion 120 is integrally molded.

As shown in FIG. 3, the lens 500 is formed with a long axis along the horizontal direction on the lower surface 113 of the upper housing 110.

In addition, as shown in FIGS. 4 and 5, the long-axis lenses 500 are installed on the lower surface 113 of the upper housing 110 at predetermined intervals (four rows in this embodiment) along the vertical direction.

At this time, as shown in FIGS. 3, 4 and 5, a pillar 140 protruding is formed on the lower housing 130 to support the lower surface 113 of the upper housing 110 between the long-axis lenses 500.

The pillar 140 prevents sagging between the vertical directions when pressure is applied, thereby remarkably improving durability due to impact resistance and vibration resistance.

As shown in FIG. 3, as shown in FIG. 3, two pillars 140a are formed on the left and right sides along the horizontal direction, and three pillars 140b in the middle are installed at predetermined intervals. This arrangement is for securing a passage for the withdrawal of cables.

Meanwhile, as shown in FIG. 5, a first coupling protrusion 115 and a first coupling groove 135 are formed on a surface A where the upper housing 110 and the lower housing 130 abut.

In this case, a first overflow allowable groove 125 is formed on the outer side of the first coupling groove 135 to allow overflow of the injected silicon.

On the other hand, as shown in FIG. 3, an additional pillar 150 is further formed on the upper surface of the rim of the lower housing 130 to further support the lower surface of the rim of the upper housing 110.

Since this additional pillar 150 surrounds the entire rim, it also functions as a waterproof and dustproof.

In addition, a second coupling protrusion 117 and a second coupling groove 157 are formed on the lower surface of the upper housing 110 and the upper surface of the additional pillar 150.

At this time, a second overflow allowable groove 147 is formed on the outer side of the second coupling groove 157 to allow overflow of the injected silicon.

The first coupling protrusion 115 and the first coupling groove 135 are disposed below the second coupling protrusion 117 and the second coupling groove 157.

Therefore, the configuration of the first and second overflow allowable grooves 125 and 147 is adopted and coupled to the double waterproof and dustproof structure, so that the first and second coupling protrusions 115 and 117 are combined with the first and second coupling grooves 135 The silicon of 157) is compressed, and the air layer in the remaining space is removed by the overflow of the silicon generated by the compression, and the space gap is filled to form a perfect double waterproof and dustproof structure.

Moreover, a packing (not shown) is further installed on the surface A where the upper housing 110 and the lower housing 130 abut, so that a triple waterproof and dustproof structure can be taken.

The present invention is not limited to the specific preferred embodiments described above, and any person of ordinary skill in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications. Of course, it is added that such changes will fall within the scope of the claims description.

1: floor type pedestrian traffic light 100: housing
110,130: upper and lower housing 115,117: first and second coupling protrusions
135,157: first and second coupling grooves 125,147: first and second overflow allowable grooves
140: pillar 150: additional pillar
300: LED module 310: PCB
330: light source (LED) 500: lens
510: concave groove 511: upper inner refractive wall
511a, 511b: first and second phase inner refractive walls 513,515: left and right inner refractive walls
517,519: left and right outer reflective walls

Claims (4)

A housing including a transparent upper housing and a lower housing;
An LED module including a PCB installed inclined to the right (in the direction of India) in the lower housing and an LED mounted on the PCB;
Including a lens integrally molded on the lower surface of the upper housing,
The lens has a left and right asymmetric parabolic shape convex downward with respect to the vertical optical axis z of the LED,
A groove on which the LED is placed is formed at the vertex of the lens, and is asymmetric left and right with respect to the vertical optical axis z,
The groove includes an image inner refractive wall and a left and right inner refractive wall through which the light of the LED is incident and refracted,
The image inner refracting wall has a first image inner refracting wall having a curved surface convex downward around the vertical optical axis z on the left, and a second flat surface having a parallel flat surface at the same inclination as the PCB on the right side. It is divided into an upper inner refractive wall,
The left and right inner refractive walls of the lens are arranged such that the 1a, 1b inclination angles (θ1a) (θ1b) in the direction opening downward with respect to the vertical optical axis z are θ1a <θ1b,
The left and right outer reflective walls of the lens are arranged such that the 2a, 2b inclination angles (φ2a) (φ2b) in a direction opening upward with respect to the vertical optical axis (z) are φ2a <φ2b.
The method according to claim 1,
The lens is formed with a long axis along the transverse direction of the upper housing,
The long-axis lenses are installed at predetermined intervals along the longitudinal direction of the upper housing,
A floor-type walking signal light in which a pillar supporting a lower surface of the upper housing protrudes between the long axis lenses in the lower housing.
The method according to claim 1,
A first coupling protrusion and a first coupling groove are formed on the lower surface of the upper housing and the upper surface of the lower housing in contact with each other,
A first overflow allowable groove is formed at an upper outside of the first coupling groove to allow overflow of the injected silicon,
An additional pillar further protruding is formed on the rim of the lower housing to further support the lower surface of the rim of the upper housing,
A second coupling protrusion and a second coupling groove are formed on the lower surface of the rim of the upper housing and the upper surface of the additional pillar,
A second overflow allowable groove is formed on the outer side of the upper portion of the second coupling groove to allow overflow of the injected silicon,
The first coupling protrusion and the first coupling groove is a floor-type walking traffic light disposed below the outer side of the second coupling protrusion and the second coupling groove.
The method according to any one of claims 1 to 3,
A floor-type walking signal light in which an anti-slip protrusion is integrally molded on the upper surface of the upper housing.

Images