KR102645715B1 - Anti-slip device - Google Patents

Abstract

The present invention relates to an anti-slip device that improves nighttime visibility through uniform light emission over the entire area, effectively protects light-emitting diodes from moisture penetration, and is easy to install and maintain. The anti-slip device according to the present invention is A light emitting device that emits light by power generated through a solar cell module; A mounting guide device that provides a mounting space for the light emitting device and the anti-slip member; and an anti-slip member mounted on the mounting guide device, wherein the mounting guide device includes a vertical support member provided in close contact with the vertical surface of the staircase, a lower seating member and an upper seating member provided on the horizontal surface of the staircase. It is composed of a member, and the lower seating member and the upper seating member are arranged in a parallel form at a certain distance in the vertical direction to provide a light emitting member mounting portion, which is a space for mounting the light emitting device, and the central portion of the upper seating member has a certain width. It forms an opening along the longitudinal direction of the upper seating member, and is characterized in that the area provided with the light-emitting diode PCB of the light-emitting device is exposed through the open portion of the upper seating member.

Description

Anti-slip device

The present invention relates to an anti-slip device, and more specifically, to an anti-slip device that improves nighttime visibility through uniform light emission over the entire area, effectively protects light-emitting diodes from moisture penetration, and is easy to install and maintain. It's about.

Anti-slip members are installed at the corners of stairs where people step on to prevent slipping, and these anti-slip members for stairs are also called non-slip for stairs.

Research on anti-slip members for stairs continues due to various demands. For example, research is being conducted on more effective materials for preventing slipping, durability of anti-slip members, nighttime visibility of anti-slip members, and ease of installation of anti-slip members.

There have been recent examples of using high-hardness materials as a more effective material for preventing slipping, and the durability of anti-slip materials can also be improved through these high-hardness materials. For example, Korean Patent No. 865289 proposes a technology that combines a layer of ultra-hard ceramic particles with a metal plate.

Since stairs are frequently used at night, visibility at night must be ensured. To this end, a number of patents have been applied for anti-slip members combined with lighting devices. Korean Patent No. 2028358 proposes a technology to improve brightness by minimizing contamination by foreign substances by beading phosphorescent pigments. Korean Patent No. 1864471 proposes a technology for applying a luminescent material with excellent afterglow characteristics and protecting the luminous material from the external environment through a coating layer. In addition to the above-mentioned patents, Korean Patent No. 1000562, Korean Patent No. 865289, and Korean Patent No. 977087 also apply phosphorescent materials for nighttime visibility of anti-slip members.

However, although phosphorescent materials have the advantage of superior afterglow characteristics compared to fluorescent materials, they have the characteristic of being discolored by ultraviolet rays over time and reducing the luminous intensity. In most of the above-mentioned patents, the photoluminescence-related members are not mounted in an easily removable structure, so they are not suitable for applications where long-term luminescence characteristics must be guaranteed, such as stairs. Additionally, depending on the type, luminescent materials may cause environmental pollution.

Meanwhile, Korea Patent Publication No. 2019-128277 provides a technology that provides a linear optical fiber between non-slips, transmits light to the optical fiber by an LED lamp, and operates the LED lamp by power accumulated by a solar cell. is presenting.

However, the technology disclosed in Korean Patent Publication No. 2019-128277 increases installation costs as solar cells must be installed on each staircase, and since light is transmitted from an LED lamp provided at one end of the optical fiber to the optical fiber, the optical fiber It has the disadvantage of not emitting light uniformly throughout the entire range. In addition, when applying an LED lamp, moisture penetration must be considered, but no configuration for moisture penetration resistance is provided, and it has a complex structure in terms of installation and maintenance.

Japanese Patent Publication No. 2002-075049 also suggests a combination of light-emitting diodes and optical fibers as lighting for stairs, except that the use of solar cells is excluded and the application of anti-slip members is excluded. Korean Patent Publication No. 2019- It is similar to the light emitting structure disclosed in No. 128277.

Korean Patent No. 865289 (announced on October 27, 2008) Korean Patent No. 2028358 (announced on October 4, 2019) Korean Patent No. 1864471 (announced on June 4, 2018) Korean Patent No. 1000562 (announced on December 15, 2010) Korean Patent No. 865289 (announced on October 27, 2008) Korean Patent No. 977087 (announced on August 20, 2010) Korean Patent Publication No. 2019-128277 (published on November 18, 2019) Japanese Patent Publication No. 2002-075049 (published March 15, 2002)

The present invention was devised to solve the above problems, and its purpose is to provide an anti-slip device that improves nighttime visibility through uniform light emission over the entire area and effectively protects the light emitting diode from moisture penetration. .

In addition, another object of the present invention is to provide a technology for easy installation and maintenance of the anti-slip device when constructing the anti-slip device by combining a light emitting device and an anti-slip member.

An anti-slip device according to the present invention for achieving the above object includes a light emitting device that emits light by power generated through a solar cell module; A mounting guide device that provides a mounting space for the light emitting device and the anti-slip member; and an anti-slip member mounted on the mounting guide device, wherein the mounting guide device includes a vertical support member provided in close contact with the vertical surface of the staircase, a lower seating member and an upper seating member provided on the horizontal surface of the staircase. It is composed of a member, and the lower seating member and the upper seating member are provided in a parallel form at a certain distance apart in the vertical direction to provide a light emitting member mounting portion, which is a space for mounting the light emitting device, and the central portion of the upper seating member has a certain width. It forms an opening along the longitudinal direction of the upper seating member, and is characterized in that the area provided with the light-emitting diode PCB of the light-emitting device is exposed through the open portion of the upper seating member.

The light emitting device provides a mounting space for the light emitting diode PCB and protects the light emitting diode PCB from the external environment, and includes a transparent protection panel that uniformly emits light emitted from the light emitting diode, and a plurality of light emitting diodes spaced apart on the PCB. It forms a structure of repeated arrangement, and includes a light emitting diode PCB mounted in the PCB mounting groove formed on the bottom of the transparent protection panel, and a light-emitting diode PCB that is sandwiched between the transparent protection panel and the lower protection sheet and is bonded between the transparent protection panel and the lower protection sheet by heat compression. A waterproof adhesive sheet is provided to seal and protect the light-emitting diode PCB mounted in the PCB mounting groove of the transparent protection panel from moisture penetration, and a waterproof adhesive sheet is provided at the bottom of the waterproof adhesive sheet to protect the waterproof adhesive sheet when heat-pressing the waterproof adhesive sheet. It is composed of a lower protection sheet that acts as a pressure plate and protects the lower part of the transparent protection panel from the external environment.

The upper surface of the transparent protective panel is divided into a first side, which is the center of the transparent protective panel, and a second side, which is the periphery of the transparent protective panel. The height of the first side is higher than the second side, so the first and second sides form a step. , the first side is exposed to the outside corresponding to the area where the PCB mounting groove provided on the lower surface of the transparent protection panel is formed, and the upper seating member of the mounting guide device is located on the second side, and the upper seating member slides on the upper seating member. The prevention member is seated.

A reflective sheet with retroreflective characteristics and a transparent color film may be sequentially stacked on at least one of the first surface of the transparent protective panel or the vertical support member of the mounting guide device.

The upper seating member is composed of a first upper seating member and a second upper seating member arranged side by side and spaced apart in the horizontal direction, and the first upper seating member and the second upper seating member are respectively positioned on the second surface of the transparent protection panel. Located in , anti-slip members are provided on the first upper seating member and the second upper seating member, respectively. When the anti-slip members are installed, the height of the anti-slip members is higher than the height of the first surface of the transparent protection panel. It is designed to

A solar cell module installed in a certain location and supported on a stand, a storage battery that stores the power produced by the solar cell module, and a control unit that controls supplying power from the storage battery to the light emitting diode PCB according to the signal from the voltage sensor. Each light-emitting diode PCB provided in a plurality of anti-slip devices is connected to a storage battery, and according to the signal from the voltage sensor, the control unit controls the storage battery to supply power to the light-emitting diode PCB provided in each staircase.

The light emitting device is selectively attachable and detachable by sliding on the light emitting device mounting portion of the mounting guide device, and the anti-slip member is selectively attachable and detachable by fastening bolts to the first upper seating member or the second upper seating member.

An anti-slip device according to the present invention includes a light emitting device that emits light by power generated through a solar cell module; A mounting guide device that provides a mounting space for the light emitting device and the anti-slip member; and an anti-slip member mounted on the mounting guide device, wherein the mounting guide device has a shape extending along the width direction of the staircase on the vertical surface of the staircase, and has a light-emitting device mounting portion that is a mounting space for the light-emitting device. It is composed of a light-emitting device mounting member and a horizontal member provided in close contact with the horizontal surface of the stairs to provide a seating space for the anti-slip member. When the light-emitting device is mounted on the light-emitting member mounting portion of the light-emitting device mounting member, light is emitted. Another feature is that the area where the light emitting diode PCB of the device is provided is exposed.

The light emitting device mounting portion has an inclined shape toward the stairs below.

The bottom of the lower seating member or the bottom of the horizontal member may be processed into an uneven shape to alleviate thermal expansion.

Power supply wiring is provided at both ends of the light emitting diode PCB, i.e., the first end and the second end, respectively. The first ends of the plurality of light emitting diode PCBs are connected in parallel to each other through the first parallel conductor, and the first end of the plurality of light emitting diode PCBs is connected in parallel to each other through a first parallel conductor. The two stages are connected in parallel to each other through a second parallel conductor, and the first parallel conductor and the second parallel conductor are each electrically connected to the storage battery.

A reflective sheet with retroreflective characteristics and a transparent color film may be sequentially stacked on at least one of the first surface of the transparent protective panel or the light emitting device mounting member.

The anti-slip device according to the present invention has the following effects.

The mounting guide device has an optimal structure in which the light emitting device and the anti-slip member can be selectively attached and detached, making installation and maintenance of the anti-slip device very easy. In addition, since the light emitting devices of all stairs are connected to a single solar cell module, installation costs can be reduced, and night visibility is improved by providing uniform light emission throughout the entire width of the stairs.

1 is a perspective view of an anti-slip device according to a first embodiment of the present invention.
Figure 2 is an exploded perspective view of an anti-slip device according to a first embodiment of the present invention.
Figure 3 is a perspective view of a light-emitting device according to an embodiment of the present invention.
Figure 4 is an exploded perspective view of a light emitting device according to an embodiment of the present invention.
Figure 5 is a perspective view of an anti-slip device according to a second embodiment of the present invention.
Figure 6 is an exploded perspective view of an anti-slip device according to a second embodiment of the present invention.
Figure 7 is a reference diagram showing an example in which the anti-slip device according to the first embodiment of the present invention is mounted on stairs.
Figure 8 is a reference diagram showing an example in which the anti-slip device according to the second embodiment of the present invention is mounted on stairs.
Figure 9 is a reference diagram showing the electrical connection state between a plurality of light emitting diode PCBs and a capacitor.
Figure 10 is a reference diagram showing the night-time light-emitting state of the light-emitting device according to the present invention.

The present invention relates to an anti-slip device applied to stairs, etc., and proposes a mechanical structure that facilitates installation and maintenance of the anti-slip device when applying a light-emitting diode combined with a solar cell as lighting for the anti-slip device. We present a light emitting device structure that protects the diode from external moisture penetration and a technology that can improve the nighttime visibility of the anti-skid device through uniform light emission throughout the entire area of the anti-skid device.

As previously mentioned in 'Technology behind the invention', most anti-slip devices applied to conventional stairs use phosphorescent materials for nighttime visibility, but phosphorescent materials have problems such as discoloration over time. In the case of technology using light-emitting diodes combined with solar cells (see Patent Document 7), uniform light emission is not achieved, LED lamps are vulnerable to moisture penetration, and have complex mechanical mechanisms in terms of high installation costs and maintenance. There is a problem in that it has a structure.

Hereinafter, an anti-slip device according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to Figures 1 and 2, the anti-slip device 1 according to an embodiment of the present invention includes a light emitting device 10, a mounting guide device 20, and an anti-slip member 30.

The light emitting device 10, the mounting guide device 20, and the anti-slip member 30 are integrated and installed on each staircase. Specifically, the light emitting device 10 and the anti-slip member 30 are mounted on the mounting guide device 20, and the mounting guide device 20 equipped with the light emitting device 10 and the anti-slip member 30 is each It can be installed at the corner of the stairs (see Figure 7). Although application to stairs was used as an example, the anti-slip device according to the present invention can be installed in various places where slip prevention is required, such as slopes other than stairs.

As described above, the anti-slip device (1) according to the present invention has a structure in which the light-emitting device (10) and the anti-slip member (30) are mounted on the mounting guide device (20), and the light-emitting device (10) and the anti-slip member (30) are mounted on the mounting guide device (20). (30) has a form that is selectively removable from the mounting guide device (20), making installation and maintenance of the anti-slip device easy. This will be explained in detail later.

The light emitting device 10 is a device including a light emitting diode (LED) that emits light using power produced by a solar cell module. In order to supply power to the light emitting diode of the light emitting device 10, the anti-slip device 1 according to the present invention further includes a solar cell module and a storage battery. The solar cell module receives sunlight and produces power through photoelectric conversion, and the storage battery stores the power produced by the solar cell module and supplies it to the light-emitting diode. In addition to the solar cell module and the storage battery, a voltage sensor and a control unit that selectively controls supply of power from the storage battery to the light emitting diode according to a signal from the voltage sensor may be further included (see FIGS. 7 and 8). In the present invention, one solar cell module is provided, and a plurality of light emitting devices 10 are electrically connected to one solar cell module, and the solar cell module is installed in a place with high light reception efficiency, for example, near the top floor of a staircase. can be installed in

In detail, the light-emitting device 10 includes a transparent protection panel 110 and a printed circuit board containing a light-emitting diode (hereinafter referred to as 'light-emitting diode PCB 120'), as shown in FIGS. 3 and 4. ), a waterproof adhesive sheet 130, and a lower protective sheet 140.

The transparent protection panel 110 provides a mounting space for the light emitting diode PCB 120, protects the light emitting diode PCB 120 from the external environment, and serves to uniformly emit light emitted from the light emitting diode.

The transparent protection panel 110 has a certain length, for example, a length corresponding to the width of a staircase, and has a lower surface and an upper surface exposed to the external environment. The bottom of the transparent protection panel 110 is provided with a PCB mounting groove 113 having a certain width and depth along the longitudinal direction of the transparent protection panel 110, and a light emitting diode PCB 120 is installed within the PCB mounting groove 113. is installed.

The upper surface of the transparent protection panel 110 is divided into a first side 111 and a second side 112, where the first side 111 is the center of the transparent protective panel 110 and the second side 112 is transparent. It corresponds to the peripheral part of the protection panel 110. The height of the first surface 111 is higher than the second surface 112, and accordingly, the first surface 111 and the second surface 112 have a step.

The reason why the upper surface of the transparent protection panel 110 is composed of a first surface 111 and a second surface 112 having a step is because the anti-slip member 30 is formed on the area of the second surface 112 having a relatively low height. ) to provide space for installation. As will be explained later, the upper seating member 230 of the mounting guide device 20 is located on the second surface 112 of the upper surface of the transparent protection panel 110, and the upper seating member 230 is provided to prevent slipping. It forms a structure in which the member 30 is seated. Additionally, the area of the first surface 111 corresponds to the area where the PCB mounting groove 113 provided on the lower surface of the transparent protection panel 110 is formed. That is, the first surface 111 is located at the top of the PCB mounting groove 113.

In the transparent protection panel 110 having the above structure, the light emitting diode PCB 120 is mounted in the PCB mounting groove 113 of the transparent protection panel 110, so that the light emitting diode PCB 120 is protected from the external environment. The light emitted from the light emitting diode of the light emitting diode PCB (120) is uniformly emitted throughout the entire area of the transparent protection panel (110). The light emitting diode PCB 120 has a structure in which a plurality of light emitting diodes 122 are spaced apart and repeatedly arranged on the PCB 121.

In addition, in order to increase the diffusion efficiency of light emitted from the light emitting diode, a reflective sheet 150 with retroreflective characteristics is further provided on the first surface 111 of the upper surface of the transparent protection panel 110, and the reflective sheet 150 is provided on the reflective sheet to improve nighttime visibility. To increase the thickness, a transparent color film, for example, an EC film 160 with a primary color, may be laminated. In one embodiment, the transparent protective panel 110 may be made of a transparent polymer material, such as polycarbonate (PC).

The reflective sheet 150 and EC film 160 having the above retroreflective characteristics can be provided on the mounting guide device 20 in addition to the transparent protection panel 110 to improve visibility. In the case of the first embodiment described later, the reflective sheet 150 and the EC film 160 can be sequentially stacked on the vertical support member 210 of the mounting guide device 20, and in the second embodiment, the light emitting device is mounted. The reflective sheet 150 and the EC film 160 can be sequentially stacked on the upper surface of the member 410. If necessary, the combination of the reflective sheet 150 and the EC film 160 is configured to be installed in at least one of the above-described transparent protection panel 110 and the mounting guide device 20. You may.

The waterproof adhesive sheet 130 is provided between the transparent protection panel 110 and the lower protective sheet 140 and serves to seal between the transparent protective panel 110 and the lower protective sheet 140. With the waterproof adhesive sheet 130 interposed between the transparent protective panel 110 and the lower protective sheet 140, when a certain degree of heat and pressure is applied, the waterproof adhesive sheet 130 melts and forms the transparent protective panel 110. and the lower protection sheet 140, respectively. Accordingly, the space between the transparent protection panel 110 and the lower protection sheet 140 is sealed, and the light emitting diode PCB is mounted in the PCB mounting groove 113 of the transparent protection panel 110. (120) is protected from external physical environment and moisture infiltration environment. That is, the light emitting diode PCB 120 provided inside the transparent protection panel 110 is protected from moisture penetration as well as the external physical environment by the waterproof adhesive sheet 130. As an example, the waterproof adhesive sheet 130 may be an ethylene vinyl acetate (Ethyl Vinyl Acetate) sheet.

The lower protective sheet 140 is provided at the lower part of the waterproof adhesive sheet 130 and serves as a pressure plate for the waterproof adhesive sheet 130 when heat compression is performed on the waterproof adhesive sheet 130 and is transparent from the external environment. It serves to protect the lower part of the protection panel 110. In one embodiment, the lower protective sheet 140 may be made of polyethylene terephthalate (PET).

Meanwhile, when the light emitting device 10 is mounted on the horizontal surface of a staircase according to the first embodiment described later, the lower part of the lower protection sheet 140 is installed to prevent the light emitting device 10 from being physically damaged by the weight of a person. A buffer pad may be further provided to relieve physical shock.

Above, the detailed configuration of the light emitting device 10 has been described. Next, the mounting guide device 20 and the anti-slip member 30 will be described.

As described above, the mounting guide device 20 provides a mounting space for the light emitting device 10 and the anti-slip member 30 to allow the light emitting device 10, the anti-slip member 30, and the mounting guide device 20 to be installed. It plays a unifying role. The mounting guide device 20 is divided into two embodiments. In the first embodiment, the light emitting device 10 is mounted on the horizontal surface of the stairs, and in the second embodiment, the light emitting device 10 is mounted on the vertical surface of the stairs.

First, the first embodiment will be described. As shown in FIGS. 1 and 2, the mounting guide device 20 includes a vertical support member 210, a lower seating member 220, and an upper seating member 230. It is composed.

Assuming that each staircase is divided into a horizontal surface for a person to step on and a vertical surface perpendicular to the horizontal surface, the vertical support member 210 is provided in close contact with the vertical surface of the staircase, and the lower seating member 220 and the upper seating member ( 230) is located on the horizontal surface of the stairs. Just as the horizontal and vertical surfaces of a staircase are orthogonal, the vertical support member 210 forms a shape orthogonal to the combination of the lower seating member 220 and the upper seating member 230.

The lower seating member 220 and the upper seating member 230 are each in the form of a flat plate extending in the width direction of the stairs, and the lower seating member 220 and upper seating member 230 are spaced apart from each other by a certain distance in the vertical direction and are parallel. It is provided in the form Therefore, a certain space is provided between the lower seating member 220 and the upper seating member 230, and the space (hereinafter referred to as the 'light emitting device mounting portion 240') is defined as the mounting space for the light emitting device 10. do.

The light-emitting device 10 described above is provided on the light-emitting device mounting portion 240 provided by the lower seating member 220 and the upper seating member 230, and at this time, the light-emitting device 10 slides in a light-emitting device mounting portion ( 240) or may be detached from the light emitting device mounting portion 240.

In the upper seating member 230, the central portion of the upper seating member 230 has a predetermined width and has an open shape along the longitudinal direction of the upper seating member 230, and is formed through the open portion of the upper seating member 230. The first surface 111 of the transparent protection panel 110 is exposed.

As described above, the upper surface of the transparent protective panel 110 is divided into a first side 111 and a second side 112, and the height of the first side 111 is higher than the second side 112, so that the first side 111 has a higher height than the second side 112. It has been mentioned that the surface 111 and the second surface 112 form a step.

The central part of the upper seating member 230 has an open shape, and the upper seating member 230 is in the form of two segments arranged side by side and spaced apart in the horizontal direction, and the two segments are each of the transparent protective panel 110. It forms a structure located on two sides (112). For convenience of explanation, the two segments will be referred to as the first upper seating member 231 and the second upper seating member 232.

In summary, the central portion of the upper seating member 230 has an open shape, and the first surface 111 of the transparent protection panel 110 is exposed through the opened portion of the upper seating member 230, and the first surface 111 of the transparent protection panel 110 is exposed. It forms a structure in which a first upper seating member 231 and a second upper seating member 232 are located on the second surface 112 located on both sides of the surface 111, respectively.

Meanwhile, a light emitting diode PCB 120 is provided at the bottom of the first surface 111 of the transparent protection panel 110 as described above. Therefore, when the light emitting device 10 is mounted on the light emitting device mounting portion 240 provided by the lower mounting member 220 and the upper mounting member 230, the first surface 111 of the transparent protection panel 110 is exposed. According to the structure, the light emitted from the light emitting diode PCB 120 is emitted to the outside through the first surface 111 of the transparent protection panel 110. In addition, the light-emitting diode PCB 120 has a plurality of light-emitting diodes repeatedly arranged at regular intervals along the width direction of the staircase, so that uniform light is emitted throughout the entire width of the staircase.

The upper seating member 230, that is, the first upper seating member 231 provided on each of the two second surfaces 112 of the upper surface of the transparent protection panel 110, and the anti-slip member on the second upper seating member 232. (30) is provided. As each of the first upper seating member 231 and the second upper seating member 232 has a shape extending along the width direction of the staircase, the anti-slip member 30 also has a shape extending along the width direction of the staircase. is placed as The anti-slip member 30 may be a known anti-slip member 30. For example, an anti-slip member 30 to which a high-hardness ceramic particle layer is applied may be applied.

When the anti-slip member 30 is installed, the height of the anti-slip member 30 is designed to be higher than the height of the first surface 111 of the transparent protective panel 110. This is to minimize contact with the first surface 111 of the transparent protection panel 110 when a person steps on the anti-slip device and to increase the anti-slip effect by the anti-slip member 30. Additionally, by minimizing contact with the first surface 111 of the transparent protection panel 110, damage to the transparent protection panel 110 and the light emitting device 10 due to the weight of a person can be prevented.

The light emitting device 10 is selectively detachable by sliding on the light emitting device mounting portion 240 of the mounting guide device 20, and the anti-slip member 30 is also mounted on the top of the mounting guide device 20. It forms a structure that is selectively attachable and detachable through bolts, etc. on the member 230. Therefore, since each of the light emitting device 10 and the anti-slip member 30 has a structure that can be easily attached to and detached from the mounting guide device 20, installation and maintenance of the anti-slip device are very easy.

Above, the anti-slip device according to the first embodiment has been described. As described above, when the anti-slip device according to the present invention is mounted on stairs, it is mounted at the corner of each staircase, and each anti-slip device is connected to one solar cell module.

Specifically, a solar cell module supported on a stand is provided in a place with excellent light reception efficiency, for example, near the top of the stairs, and on one side of the solar cell module is a storage battery and a voltage sensor that stores the power produced by the solar cell module. A control unit is provided to selectively control the supply of power from the storage battery to the light emitting diode PCB 120 according to the signal (see FIG. 7). In addition, the light emitting diode PCB (120) of the anti-slip device mounted on each staircase is connected to a storage battery. In this structure, the light emitting device 10 provided at each staircase is connected to one solar cell module. Under this structure, the control unit controls the storage battery according to the signal from the voltage sensor to supply power to the light-emitting diode PCB 120 provided at each staircase, and thereby operates the light-emitting device 10 at each staircase. The voltage sensor measures the voltage of power produced by the solar cell module, and the control unit controls power to be supplied from the storage battery to the light emitting diode PCB 120 when the voltage measured by the voltage sensor is less than a certain voltage.

Next, the anti-slip device 2 according to the second embodiment will be described. As described above, in the first embodiment, the light emitting device 10 is mounted on the horizontal surface of the stairs, and in the second embodiment, the light emitting device 10 is mounted on the vertical surface of the stairs.

According to the second embodiment, as shown in FIGS. 5 and 6, the mounting guide device 40 includes a light emitting device mounting member 410 and a horizontal member 420. The light-emitting device mounting member 410 is provided in close contact with the vertical surface of the stairs to provide a mounting space for the light-emitting device 10, and the horizontal member 420 is provided in close contact with the horizontal surface of the stairs to provide a non-slip member 50. Provides seating space. The light emitting device mounting member 410 and the horizontal member 420 have orthogonal shapes.

The light-emitting device mounting member 410 extends along the width direction of the staircase on the vertical surface of the staircase, and includes a light-emitting device mounting portion 430, which is a space in which the light-emitting device 10 can be mounted. The light emitting device mounting portion 430 provided on the light emitting device mounting member 410 has the same shape as the light emitting device mounting portion 240 according to the first embodiment. Additionally, like the first embodiment, the light emitting device 10 may be mounted on the light emitting device mounting portion 430 in a manner that slides on the light emitting device mounting portion 430 or may be detached from the light emitting device mounting portion 430. In addition, when the light-emitting device 10 is mounted on the light-emitting member mounting portion of the light-emitting device mounting member 410, the first surface 111 of the transparent protection panel 110 of the light-emitting device 10 is exposed to the outside. Again, it is the same as the first embodiment.

Meanwhile, the light emitting device mounting unit 430, that is, the light emitting device 10 mounted on the light emitting device mounting unit 430, has a shape inclined at a certain angle to face the stairs below. This is to improve visibility of the stairs by allowing the light emitted by the light emitting device 10 to illuminate the stairs below. In one embodiment, the light emitting device mounting portion 430 may be inclined at an angle of 5 to 7 degrees.

The horizontal member 420, like the light emitting device mounting member 410, has a shape extending along the width direction of the stairs, and is seated on the upper surface of the anti-slip member 50, which is a space where the anti-slip member 50 is seated. A groove is provided. The anti-slip member 50 is seated in the anti-slip member 50 seating groove of the horizontal member 420, and can be selectively attached and detached through bolt fastening.

Additionally, the bottom of the horizontal member 420, that is, the bottom of the horizontal member 420 that is in close contact with the horizontal surface of the stairs, may be processed into an uneven shape to alleviate thermal expansion of the horizontal member 420 due to a rise in temperature. This uneven processing can also be applied in the first embodiment. That is, it is also possible to apply uneven processing to the bottom of the lower seating member of the first embodiment.

Above, the anti-slip devices 1 and 2 according to the first and second embodiments have been described. As described above, according to the first or second embodiment of the present invention, the light emitting device 10 and the anti-slip members 30 and 50 can be selectively attached and detached from the mounting guide device 20 and 40. It can be seen that it has an optimal structure, which makes installation and maintenance of the anti-slip device very easy. In addition, as the light emitting devices of all stairs are connected to one solar cell module, installation costs can be reduced, and night visibility is improved by providing uniform light emission across the entire width of each staircase. It can be improved.

Meanwhile, in implementing the first and second embodiments, power is supplied to the light emitting diode PCBs 120 arranged on all stairs with low power, and a plurality of light emitting diodes provided in each light emitting diode PCB 120 are used. In order to ensure that (122) emits light with uniform illuminance, the following circuit configuration is applied.

Referring to FIG. 9, the light emitting diode PCB 120 is provided with power supply wiring at both ends, that is, the first end and the second end, and a plurality of light emitting diode PCBs 120 arranged on each staircase are electrically connected in parallel. do. Specifically, the plurality of light emitting diode PCBs 120 are connected in parallel to each other through the first end and are also connected in parallel to each other through the second end. If the wiring structure of the first single-side parallel connection is referred to as the first parallel conductor 510 and the wiring structure of the second single-side parallel connection is referred to as the second parallel conductor 520, the first stage of the plurality of light-emitting diode PCB 120 It can be expressed that they are connected in parallel to each other through the first parallel conductor 510, and the second ends of the plurality of light emitting diode PCBs 120 are connected in parallel to each other through the second parallel conductor 520.

The first parallel conductor 510 and the second parallel conductor 520 are each electrically connected to a storage battery, and power is supplied to each of the first parallel conductor 510 and the second parallel conductor 520 through the storage battery. That is, the power of the storage battery is supplied to the first end of each light-emitting diode PCB 120 through the first parallel conductor 510, and at the same time, the power of the storage battery is supplied to the first end of each light-emitting diode PCB 120 through the second parallel conductor 520. 2 Supplied on one side.

The reason for supplying power to both ends of the light emitting diode PCB 120 through the first parallel conductor 510 and the second parallel conductor 520 is to ensure uniformity of all light emitting diodes 122 provided on the light emitting diode PCB 120. This is to induce light emission and to enable power supply to the light emitting diode PCB 120 even when one of the first parallel conductor 510 and the second parallel conductor 520 is disconnected (open).

The light emitting diode PCB (120) is installed on stairs, etc., and has a certain length as described above, so when power is supplied to only one end of the light emitting diode PCB (120), the farther away from the power supply wiring, the more resistance the supply causes. The amount of power generated becomes smaller. In other words, the light emitting diode 122 that is close to the power supply wiring has excellent illuminance, but the illuminance becomes weaker as the light emitting diode 122 moves away from the power supply wiring. To prevent this, the amount of power supplied to each light emitting diode PCB 120 must be increased, which requires the installation of an additional solar cell module. On the other hand, when power is supplied to both ends of the light emitting diode PCB 120 as in the embodiment of the present invention, all light emitting diodes 122 of the light emitting diode PCB 120 are maintained at uniform illumination through a relatively small amount of power. It can emit light.

In addition, even if one of the first parallel conductor 510 and the second parallel conductor 520 is open, power can be supplied through any end of the light emitting diode PCB 120 through the remaining parallel conductor, so that the light emitting device can be operated stably.

1, 2: anti-slip device 10: light emitting device
20: Mounting guide device 30, 50: Anti-slip member
110: transparent protection panel 111: first side
112: 2nd side 113: PCB mounting groove
120: Light emitting diode PCB 121: PCB
122: light emitting diode 130: waterproof adhesive sheet
140: Lower protection sheet 150: Reflective sheet
160: EC film
210: Vertical support member
220: lower seating member 230: upper seating member
231: first upper seating member 232: second upper seating member
240, 430: Light emitting device mounting part
410: Light emitting device mounting member 420: Horizontal member
510: first parallel conductor 520: second parallel conductor

Claims (15)

A light emitting device that emits light by power generated through a solar cell module;
A mounting guide device that provides a mounting space for the light emitting device and the anti-slip member; and
It includes a non-slip member mounted on the mounting guide device,
The mounting guide device includes a vertical support member provided in close contact with the vertical surface of the stairs, a lower seating member and an upper seating member provided on the horizontal surface of the stairs,
The lower seating member and the upper seating member are provided in a parallel form with a certain distance apart in the vertical direction, and a light emitting member mounting portion, which is a space where the light emitting device is mounted, is provided,
The central portion of the upper seating member has a certain width and has an opening along the longitudinal direction of the upper seating member, and the area provided with the light emitting diode PCB of the light emitting device is exposed through the open portion of the upper seating member,
The light emitting device is,
A transparent protection panel that provides a mounting space for the light emitting diode PCB, protects the light emitting diode PCB from the external environment, and evenly dissipates the light emitted from the light emitting diode,
A light-emitting diode PCB, which has a structure in which a plurality of light-emitting diodes are spaced apart and repeatedly arranged on the PCB, and is mounted in a PCB mounting groove formed on the bottom of the transparent protection panel,
A waterproof adhesive sheet that is sandwiched between the transparent protection panel and the lower protection sheet and seals the space between the transparent protection panel and the lower protection sheet by heat compression, thereby protecting the light emitting diode PCB mounted in the PCB mounting groove of the transparent protection panel from moisture penetration. and,
It is provided at the bottom of the waterproof adhesive sheet and serves as a pressure plate for the waterproof adhesive sheet during thermal compression of the waterproof adhesive sheet, and includes a lower protective sheet that protects the lower part of the transparent protective panel from the external environment.
The upper surface of the transparent protective panel is divided into a first side, which is the center of the transparent protective panel, and a second side, which is the periphery of the transparent protective panel. The height of the first side is higher than the second side, so the first and second sides form a step. ,
The first side is exposed to the outside corresponding to the area where the PCB mounting groove provided on the lower surface of the transparent protection panel is formed, and the upper seating member of the mounting guide device is located on the second side, and a non-slip surface is provided on the upper seating member. The member is settled,
The upper seating member consists of a first upper seating member and a second upper seating member arranged side by side and spaced apart in the horizontal direction,
The first upper mounting member and the second upper mounting member are each located on the second side of the transparent protective panel, and anti-slip members are provided on the first upper mounting member and the second upper mounting member, respectively,
When the anti-slip member is installed, the height of the anti-slip member is designed to be higher than the height of the first surface of the transparent protective panel,
A solar cell module installed in a certain location and supported on a stand, a storage battery that stores the power produced by the solar cell module, and a control unit that controls supplying power from the storage battery to the light emitting diode PCB according to the signal from the voltage sensor. It consists of:
Each light-emitting diode PCB provided in a plurality of anti-slip devices is connected to a storage battery, and according to the signal from the voltage sensor, the control unit controls the storage battery to supply power to the light-emitting diode PCB provided in each staircase.
The bottom of the lower seating member is processed into an uneven shape to alleviate thermal expansion.
Power supply wiring is provided at both ends of the light emitting diode PCB, the first and second ends, respectively.
The first ends of the plurality of light emitting diode PCBs are connected in parallel to each other through a first parallel conductor, and the second ends of the plurality of light emitting diode PCBs are connected in parallel to each other through a second parallel conductor,
The first parallel conductor and the second parallel conductor are each electrically connected to the storage battery,
An anti-slip device, characterized in that the waterproof adhesive sheet is an ethylene vinyl acetate sheet.
delete delete The method of claim 1, wherein a reflective sheet with retroreflective characteristics and a transparent color film are sequentially stacked on at least one of the first surface of the transparent protective panel or the vertical support member of the mounting guide device. Anti-slip device.
delete delete The method of claim 1, wherein the light emitting device is selectively detachable by sliding on the light emitting device mounting portion of the mounting guide device, and the anti-slip member is attached to the first upper mounting member or the second upper mounting member by bolting. An anti-slip device that is selectively removable.
A light emitting device that emits light by power generated through a solar cell module;
A mounting guide device that provides a mounting space for the light emitting device and the anti-slip member; and
It includes a non-slip member mounted on the mounting guide device,
The mounting guide device is,
A light-emitting device mounting member that extends along the width direction of the staircase on the vertical plane of the staircase and includes a light-emitting device mounting portion that is a mounting space for the light-emitting device;
It consists of a horizontal member that is provided in close contact with the horizontal surface of the stairs and provides a seating space for the anti-slip member,
When the light emitting device is mounted on the light emitting member mounting part of the light emitting device mounting member, the area provided with the light emitting diode PCB of the light emitting device is exposed,
The light emitting device mounting portion is inclined toward the stairs below,
The light emitting device is,
A transparent protection panel that provides a mounting space for the light emitting diode PCB, protects the light emitting diode PCB from the external environment, and evenly dissipates the light emitted from the light emitting diode,
A light-emitting diode PCB, which has a structure in which a plurality of light-emitting diodes are spaced apart and repeatedly arranged on the PCB, and is mounted in a PCB mounting groove formed on the bottom of the transparent protection panel,
A waterproof adhesive sheet that is sandwiched between the transparent protection panel and the lower protection sheet and seals the space between the transparent protection panel and the lower protection sheet by heat compression, thereby protecting the light emitting diode PCB mounted in the PCB mounting groove of the transparent protection panel from moisture penetration. and,
It is provided at the bottom of the waterproof adhesive sheet and serves as a pressure plate for the waterproof adhesive sheet during thermal compression of the waterproof adhesive sheet, and includes a lower protective sheet that protects the lower part of the transparent protective panel from the external environment.
The upper surface of the transparent protective panel is divided into a first side, which is the center of the transparent protective panel, and a second side, which is the periphery of the transparent protective panel. The height of the first side is higher than the second side, so the first and second sides form a step. ,
The first side is exposed to the outside in correspondence with the area where the PCB mounting groove provided on the bottom of the transparent protection panel is formed,
A solar cell module installed in a certain location and supported on a stand, a storage battery that stores the power produced by the solar cell module, and a control unit that controls supplying power from the storage battery to the light emitting diode PCB according to the signal from the voltage sensor. It consists of:
Each light-emitting diode PCB provided in a plurality of anti-slip devices is connected to a storage battery, and according to the signal from the voltage sensor, the control unit controls the storage battery to supply power to the light-emitting diode PCB provided in each staircase.
The bottom of the horizontal member is processed into an uneven shape to alleviate thermal expansion.
Power supply wiring is provided at both ends of the light emitting diode PCB, the first and second ends, respectively.
The first ends of the plurality of light emitting diode PCBs are connected in parallel to each other through a first parallel conductor, and the second ends of the plurality of light emitting diode PCBs are connected in parallel to each other through a second parallel conductor,
The first parallel conductor and the second parallel conductor are each electrically connected to the storage battery,
An anti-slip device, characterized in that the waterproof adhesive sheet is an ethylene vinyl acetate sheet.
delete delete delete The anti-slip device according to claim 8, wherein a reflective sheet with retroreflective characteristics and a transparent color film are sequentially stacked on at least one of the first surface of the transparent protective panel or the light emitting device mounting member. . delete delete delete