KR20210144346A - Rooftop Green Optical Sighting System - Google Patents

Abstract

The present invention relates to an optical anti-corrosion system for roof greening. The optical anti-corrosion system for the roof greening of the present invention, in order to protect a joint unit of a waterproof sheet by irradiating a light from a light source including a sunlight to the joint unit of a waterproof sheet embedded in a soil layer and killing plant roots, comprises: the waterproof sheet (10); a soil layer (20); and a light transmitting member (30).

Description

Rooftop Green Optical Sighting System {Rooftop Green Optical Sighting System}

The present invention relates to an optical anti-corrosion system for roof greening, and more particularly, by irradiating light from a light source including sunlight to the joint of a waterproof sheet embedded in the soil layer, the joint of the waterproof sheet in an optical method to kill plant roots. It relates to an optical anti-corrosion system for roof greening that protects.

In general, in waterproofing for roof greening, the lack of urban green space due to rapid urbanization is emerging as a global problem, not just in Korea, so the greening industry for building structures has been researched and developed mainly in Europe, North America, and Japan. In accordance with these technological trends, the development of related technologies has begun by recognizing the importance of roof greening in Korea and examining advanced technologies.

Accordingly, in Patent No. 10-1202763 disclosed in the prior art, a synthetic resin film having waterproof and anti-rust properties is laminated on an upper surface of a metal film as a central substrate, and a polyester (PET) nonwoven fabric is laminated on the lower surface to form a three-layered layer. anti-corrosive layer; a rubber asphalt compound layer applied to the lower end of the anti-corrosion layer and elastically accommodating the load of soil and tree planting; a release layer attached to the bottom of the rubber asphalt compound layer; and a technology including a watertight reinforcing anti-corrosion tape installed at a connection portion between the anti-corrosion layers has been previously registered.

In the prior art, since the joint between the anti-corrosion layers is finished by the anti-corrosive tape, if the joint parts are not uniformly melted and adhered, the plant roots easily dig in, and cracks, water leaks and Disadvantages followed, leading to breakage of the waterproofing layer.

Accordingly, the present invention was conceived to solve the above problem, and protects the joint of the waterproof sheet in an optical method that kills plant roots by irradiating light from the light source including sunlight toward the joint of the waterproof sheet embedded in the soil layer. An object of the present invention is to provide an optical anti-corrosion system for rooftop greening.

In order to achieve this object, a feature of the present invention is a waterproof sheet 10 for waterproofing the roof surface by being connected to form a joint 12 at the end in the width direction; a soil layer 20 formed on the waterproof sheet and provided to plant plants; and a light transmitting member 30 embedded in the soil layer 20 and provided to irradiate the light of the light source including sunlight toward the joint 12 of the waterproof sheet 10; do.

At this time, the light transmitting member 30 is formed in a plate shape and the upper end is exposed to the outside of the soil layer 20 to receive light from the light source unit 30a, and the lower end light input through the light input unit 30a. It is characterized in that the light output unit (30b) for outputting to the joint (12) side of the waterproof sheet (10) is formed.

In addition, the light transmitting member 30 is formed of a bundle of optical fibers, the upper end of which is exposed to the outside of the soil layer 20 to receive light from the light source unit 30a, and the lower end is the light input through the light input unit 30a. It is characterized in that the light output unit (30b) for outputting to the joint (12) side of the waterproof sheet (10) is formed.

In addition, it is characterized in that the light collecting plate 40 is installed on the upper end of the light transmission member 30 to condense sunlight toward the light input unit 30a is provided.

In addition, the light transmitting member 30 is characterized in that the auxiliary light source unit 32 including an LED module is further provided.

In addition, the light output unit 30b of the light transmitting member 30 includes a pair of vertical optical plates 34 and a horizontal transparent plate 36 connecting the pair of vertical optical plates 34 to each other at the upper end. Consists of, characterized in that the joint 12 is provided so as to receive and protect in the compartment formed by the pair of vertical optical plate (34) and the horizontal transparent plate (36).

According to the above configuration and action, the present invention has an effect of protecting the joint of the waterproof sheet by irradiating the light from the light source including sunlight to the joint of the waterproof sheet embedded in the soil layer to kill the plant root.

1 is a block diagram showing a plate-shaped light transmission member of an optical anti-corrosion system for roof greening according to an embodiment of the present invention.
2 is a configuration diagram showing an optical fiber type light transmission member of the optical root control system for roof recording according to an embodiment of the present invention.
3 is a block diagram showing a light collecting plate of an optical anti-corrosion system for rooftop greening according to an embodiment of the present invention.
4 is a block diagram illustrating an auxiliary light source unit of an optical anti-corrosion system for rooftop greening according to an embodiment of the present invention.
5 is a block diagram showing a modified example of the light output unit of the optical anti-corrosion system for roof recording according to an embodiment of the present invention.

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

The present invention relates to an optical anti-corrosion system for roof greening, which is an optical method that kills plant roots by irradiating light from a light source including sunlight toward the joint of a waterproof sheet embedded in the soil layer to protect the joint of the waterproof sheet. The waterproof sheet 10, the soil layer 20, and the light transmission member 30 are the main components.

The waterproof sheet 10 according to the present invention is connected to form a joint 12 at the end in the width direction to waterproof the roof surface. The waterproof sheet 10 may be configured to form the joint 12 by butt-connecting or overlapping the ends thereof, and attaching a separate anti-corrosion tape (verb embedding) to the upper surface of the joint.

In addition, the soil layer 20 according to the present invention is formed on the waterproof sheet and is provided so that plants are planted. Then, plants are planted in the soil layer 20 to green the roof (flower bed).

In addition, the light transmitting member 30 according to the present invention is installed to be embedded in the soil layer 20 , and is provided to irradiate the light of the light source including sunlight toward the joint 12 of the waterproof sheet 10 . The light transmitting member 30 has a structure with a high refractive index inside (core) and a low refractive index at the outside (clad), so that light travels in a form trapped in the core while repeating total reflection at the boundary. is a configuration that

And, when light from the light source unit is irradiated toward the joint 12 of the waterproof sheet 10 through the light transmission member 30 , some roots that are active toward the joint 12 among the plant roots active in the soil layer 20 . It performs the anti-corrosion function in an optical way that is killed by the light from the light source.

In Figure 1, the light transmitting member 30 is formed in a plate shape, the upper end is exposed to the outside of the soil layer 20, the light source unit light is input through the light input unit (30a), and the lower end through the light input unit (30a) A light output unit 30b for outputting light toward the joint 12 of the waterproof sheet 10 is formed.

That is, after installing the waterproof sheet 10 on the roof floor, the light output portion 30b of the plate-shaped light transmission member 30 is installed at a position corresponding to the joint 12 of the waterproof sheet 10 to match. Then, the soil layer 20 is formed on the upper surface of the waterproof sheet 10 , and the light input unit 30a of the waterproof sheet 10 protrudes higher than the surface layer of the soil layer 20 and is provided in an exposed type.

Accordingly, the light (solar light or LED module) of the light source unit is input through the light input unit 30a of the plate-shaped light transmission member 30 and output to the inside of the soil layer 20 through the light output unit 30b, so the joint part ( 12) is provided so as to wither away the roots that are exposed to the light (solar light or LED module) of the light source unit to the side of the joint 12 .

In FIG. 2 , the light transmitting member 30 is formed of a bundle of optical fibers and the upper end is exposed to the outside of the soil layer 20 to receive light from the light source unit 30a, and the lower end is input through the light input unit 30a. A light output unit 30b for outputting the applied light toward the joint 12 of the waterproof sheet 10 is formed.

That is, after the waterproof sheet 10 is installed on the roof floor, the optical output part 30b of the optical fiber bundle type light transmission member 30 matches the position corresponding to the joint part 12 of the waterproof sheet 10 . and then the soil layer 20 is formed on the upper surface of the waterproof sheet 10, and the light input unit 30a of the waterproof sheet 10 extends in the longitudinal direction from the light output unit 30b, compared to the soil layer 20 surface layer It protrudes high or extends in a bundle form and protrudes high from the soil layer 20 to receive sunlight. On the other hand, a configuration in which a plate-shaped diffusion plate having a structure surrounding the joint portion 12 of the waterproof sheet 10 is installed in the light output portion 30b of the bundle-type light transmission member 30 is also possible.

Accordingly, the light (solar light or LED module) of the light source unit is input through the light input unit 30a of the optical fiber bundle type light transmission member 30 and output to the inside of the soil layer 20 through the light output unit 30b. The part 12 is exposed to the light (solar light or LED module) of the light source part and is provided so as to wither away the root which is attached to the joint part 12 side.

In FIG. 3 , a light collecting plate 40 installed at the upper end of the light transmitting member 30 to collect sunlight toward the light input unit 30a is provided. The light collecting plate 40 is formed of a reflecting plate, and the angle of the hinge installed on the fixed plate is adjusted with respect to the axis, and the light source unit light source including sunlight is reflected through the light collecting plate 40 to the light input unit of the light transmitting member 30 ( 30a), so the optical anti-corrosion efficiency using light is improved.

In FIG. 4 , an auxiliary light source unit 32 including an LED module is further provided on the light transmitting member 30 . The auxiliary light source unit 32 is insert-molded in the light transmission member 30 or installed at a position corresponding to the light input unit 30a, and is controlled on/off by the control unit. In this case, the control unit continuously irradiates the light source even when the sunlight is low during the daytime or is turned on at night and the sunlight is weak to improve the optical rooting efficiency.

In FIG. 5, the light output unit 30b of the light transmitting member 30 includes a pair of vertical optical plates 34 and a horizontal transparent plate connecting a pair of vertical optical plates 34 to each other at the upper end ( 36), and the joint 12 is accommodated and protected in the compartment formed by the pair of vertical optical plates 34 and the horizontal transparent plate 36.

As such, since the joint 12 is protected within the compartment formed by the pair of vertical light plates 34 and the horizontal transparent plate 36, root penetration is physically blocked and the light source output from the light output unit 30b Root penetration is optically blocked by

Accordingly, the optical rooting efficiency is improved by the auxiliary light source 32, and the joint 12 of the waterproof sheet 10 is visually checked from the outside through the horizontal transparent plate 36 to prevent cracks, root penetration, and poor adhesion. By accurately judging the damage included and accurately detecting the location of the damage, it aims to shorten the construction period and reduce the cost of repair work.

10: waterproof sheet 20: soil layer
30: light transmission member

Claims (6)

A waterproof sheet 10 for waterproofing the roof surface by being connected to form a joint 12 at the end in the width direction;
a soil layer 20 formed on the waterproof sheet and provided to plant plants; and
A light transmission member 30 installed to be embedded in the soil layer 20 and provided to irradiate the light of the light source including sunlight toward the joint 12 of the waterproof sheet 10; characterized in that it comprises a Optical anti-corrosion system for rooftop greening. The method of claim 1,
The light transmission member 30 is formed in a plate shape, the upper end of which is exposed to the outside of the soil layer 20 to receive light from the light source unit 30a, and the light inputted through the light input unit 30a at the lower end of the waterproof sheet (10) An optical anti-corrosion system for roof greening, characterized in that the light output unit (30b) for outputting to the side of the joint (12) is formed. The method of claim 1,
The light transmitting member 30 is formed of a bundle of optical fibers, the upper end of which is exposed to the outside of the soil layer 20, and the light input unit 30a to which light from the light source is input, and the light input through the light input unit 30a at the lower end, waterproofing An optical anti-corrosion system for roof greening, characterized in that a light output unit (30b) outputting to the joint (12) side of the sheet (10) is formed. 3. The method of claim 1 or 2,
An optical anti-corrosion system for roof greening, characterized in that a light collecting plate (40) is installed at the upper end of the light transmitting member (30) and condensing sunlight toward the light input unit (30a). 3. The method of claim 1 or 2,
An optical anti-corrosion system for roof recording, characterized in that the light transmitting member (30) further includes an auxiliary light source unit (32) including an LED module. 4. The method according to any one of claims 1 to 3,
The light output unit 30b of the light transmission member 30 is composed of a pair of vertical optical plates 34 and a horizontal transparent plate 36 connecting the pair of vertical optical plates 34 to each other at the upper end. and a joint (12) in a compartment formed by the pair of vertical optical plates (34) and horizontal transparent plates (36) to be accommodated and protected.

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