KR102139027B1 - Landscape native environment system - Google Patents

Abstract

The present invention relates to a landscape native environment system. More particularly, the present invention relates to a landscape native environment system comprising: a heat generating module buried in the ground and located on a lower part of roots of landscape trees; a heat-insulating reflective film formed with a side wall surrounding the heat generating module while having a predetermined inclination; a thermal insulation cover unit installed on a lower part of landscape trees to reflect heat of the heat generating module to the ground; and a control unit equipped with a soil temperature sensor for controlling the operation of the heat generating module by sensing the temperature of the ground.

Description

LANDSCAPE NATIVE ENVIRONMENT SYSTEM}

The present invention relates to a landscaping indigenous environment system, and more specifically, a heat generating module that supplies heat to the roots of tropical landscaped water and a heat-retaining cover that is installed at the bottom of the landscaped water and reflects heat traveling to the ground to the ground. It relates to a landscaping indigenous environment system that can save power consumption while preventing landscaping in the winter, including a control unit that controls the operation of the heat generating module by a sensor.

In general, greenhouses such as plastic greenhouses require heating to form growth conditions for plant cultivation.

The heating system of a conventional greenhouse is equipped with a boiler that heats water by burning fossil fuels such as oil or gas, and a metal pipe or PVC pipe that circulates and stores the water heated in the boiler, and circulates the heated water to heat it. Do it.

This conventional heating system uses expensive oil or gas as fuel, and thus requires a high heating cost. In addition, since the boiler that burns oil or gas is expensive, there is a problem in that an expensive facility cost is required to construct it in a greenhouse system.

In addition, in the conventional heating system, a space for installing a boiler having a large volume must be provided, so the installation location is limited, and heating is performed while the heated water is circulated, so heat loss is very large and a temperature difference occurs depending on the location in the greenhouse. There was a problem.

Since the above-mentioned conventional heating system is cooled while water circulates along the pipe, the temperature at the near side of the boiler is high and the temperature at the far side of the boiler is relatively low.

Therefore, it is difficult to uniformly heat the interior of the greenhouse at a temperature suitable for the plant to be cultivated and maintain the proper temperature.

In addition, a secondary problem in which the growth of plants in the greenhouse is restricted is caused, and there is a problem in that it takes a lot of cost to maintain the heating system.

Also, in addition to the circulating boiler type, a heater-type heating device is used in a greenhouse for plant cultivation, but it also takes a lot of cost, risks fire, and reduces moisture in the greenhouse to remove humidity in the air, hindering growth and continuing. Therefore, there was a problem of supplying moisture.

In such a conventional technique, a hot wire buried meal in which a hot wire that emits heat is used is buried.

Accordingly, by raising the temperature of the soil by the heat emitted from the buried hot wire, the growth of plants is made actively.

However, the conventional hot wire buried type has a problem in that heat is locally radiated only around the buried hot wire, making it difficult to maintain a uniform temperature over the entire bank.

In addition, there is a problem in that the growth of the plant does not occur smoothly and the growth of the plant is prevented by the concentration phenomenon of the root due to the concentrated phenomenon in which the root of the planted plant is focused around the heating wire.

In particular, in the case of shoveling, there is a problem in that growth efficiency is deteriorated because rooting is not smoothly performed on planted branches.

In addition, in the case of a hot-wire buried type, there is a problem that the growth efficiency for plant growth or rooting of a shovel is low in preparation for power consumption and installation maintenance cost.

Republic of Korea Registered Patent No. 10-1515291 (2015.04.20. registered)

In order to solve the problems of the prior art as described above, the present invention is provided with a heat generating module for supplying heat to the roots of tropical landscaped water and a heat-retaining cover part installed under the landscaped water to reflect the heat traveling to the ground and soil temperature sensing. It is to provide a landscaping native environment system with a new structure that can save power consumption while preventing landscaping in the winter, including a control unit that controls the operation of the heat generating module by a sensor.

In addition, by forming a drain in the heat generating module to drain the water that has flowed from the ground through the ground into the heat generating module to protect the heat generating module from moisture, and adjust the moisture in the ground to create an environment where landscape water can grow naturally. It is to provide a landscaping native environment system that fosters.

The present invention to solve the above problems

A heat generating module buried in the ground and located at the bottom of the root of the landscape tree;

An insulating reflective film formed by side walls surrounding the heat generating module and forming a predetermined slope;

It is installed on the lower portion of the landscaping water insulation cover portion for reflecting the heat of the heat generating module to the ground; And

It includes a control unit equipped with a soil temperature sensor for sensing the temperature of the ground to control the operation of the heat generating module

Provide a landscape native environment system.

In the landscaping native environment system according to an embodiment of the present invention, the heat generating module is a heat generating device in which a heating wire is embedded inside to form a plate shape and a fixing frame surrounding the plate is formed; A heat insulating layer provided on the lower portion of the heat generating device to protect the loss of heat; A metal protection plate located above the heat generating device and below the heat insulating layer; And it may further include a drain for draining the water flowing into the ground to the bottom of the heat generating device.

In a landscape native environment system according to an embodiment of the present invention, the drainage portion is a drainage hole through a surface of the heat generating device to form a plurality of holes; A drain pipe which is inserted into the drain hole and formed into a pipe shape for moving moisture introduced into one surface of the heat generating device, and having a flange formed thereon; And a bolt that is spirally coupled to the lower portion of the drain pipe to firmly position the drain pipe in the heat generating device.

In the landscaping native environment system according to an embodiment of the present invention, the heat generating device may be formed of a graphene heating film to generate heat through underground heat to supply heat to the roots of the landscape water.

In the landscaping native environment system according to an embodiment of the present invention, the insulating cover portion is a plate-shaped plate portion disposed under the landscape tree; A wall portion extending in a vertical direction from a hole formed through the center of the plate portion, and a plurality of protrusions formed in a vertical direction inside the wall portion; And it is provided on the lower portion of the plate portion may further include a reflective film that reflects the heat generated by the heat generating module to move to the ground.

In the landscaping native environment system according to an embodiment of the present invention, the control unit, when reaching a predetermined temperature to the soil temperature sensor, a power unit for applying power to the heat generating module; A main circuit breaker to prevent overload of power applied to the heat generating module; Temperature controller for setting the survival temperature of the landscape tree according to the season; And it may further include a timer switch for controlling the operating time of the power supply unit to reduce the consumption of power applied to the heat generating module by the operation of the temperature controller.

The landscaping indigenous environment system according to the present invention generates heat by a heat generating module that supplies heat to the roots of tropical landscaped water and a heat-retaining cover part that is installed under the landscaped water to reflect the heat traveling to the ground and the soil temperature sensor. Including the control unit for controlling the operation of the module has the advantage of saving power consumption while preventing landscaping in the winter season.

In addition, the landscaping native environment system according to the present invention is provided with a reflective film at the bottom of the heat-retaining cover part installed under the tropical landscape water to reflect heat or far infrared rays generated from the heat generating module and moving to the ground to the ground. It has the advantage of helping the face training system.

In addition, the landscaping indigenous environment system according to the present invention includes a control unit equipped with a soil temperature sensor that senses the temperature of the ground, and applies power to the heat generating module when it reaches a preset temperature in winter or cold, According to the season, the temperature controller that can set the survival temperature of the landscape tree has the advantage of allowing the landscape tree to grow naturally by adapting to new climatic conditions.

1 is a cross-sectional view illustrating a concept of a configuration of a landscape native environment system according to an embodiment of the present invention.
2 is a plan view showing a heat generating module of the landscape native environment system according to an embodiment of the present invention in a plane.
FIG. 3 is a cross-sectional view of FIG. 2.
4 is an exemplary view showing a state in which an insulating reflective film is disposed in a landscape native environment system according to an embodiment of the present invention.
5 is an exemplary view showing a thermal insulation cover portion of a landscape native environment system according to an embodiment of the present invention.
6 is a block diagram showing a control unit of a landscape native environment system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment that can be easily carried out by the person of ordinary skill in the art to which the present invention pertains. However, in the detailed description of the operating principle of the preferred embodiment of the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

In addition, the same reference numerals are used for parts having similar functions and functions throughout the drawings.

In addition, when it is said that a part is'connected' with another part in the whole specification, it includes not only the case of being directly connected, but also the case of being connected indirectly with other components in between. In addition, "including" a component means that other components may be further included instead of excluding other components, unless otherwise stated.

Also,'landscape trees' used throughout the specification includes designating plants or trees growing in tropical and subtropical regions. In addition,'heat or warm' includes not only the heat generated by the heat generating module, but also indicating far infrared rays.

Hereinafter, a landscape native environment system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a concept of a configuration of a landscape native environment system according to an embodiment of the present invention, and FIG. 2 is a plan view showing a heat generating module of a landscape native environment system according to an embodiment of the present invention in a plan view, 3 is a cross-sectional view showing FIG. 2 in cross-section, FIG. 4 is an exemplary view showing a state in which a heat-insulating reflective film is disposed in a landscape native environment system according to an embodiment of the present invention, and FIG. 5 is a landscaping according to an embodiment of the present invention It is an exemplary view showing a thermal insulation cover part of a native environment system, and FIG. 6 is a configuration diagram showing a control unit of a landscape native environment system according to an embodiment of the present invention.

As shown in FIG. 1, the landscape native environment system 10 according to an embodiment of the present invention includes a heat generating module 100, an insulating reflective film 200, a heat insulating cover part 300, and a control part 400. .

More specifically, as shown in FIG. 1, the landscaping native environment system 10 according to an embodiment of the present invention is embedded in the ground (G) and a heat generating module located at the bottom of the root of the landscape tree (T) ( 100), an insulating reflective film 200 formed of side walls surrounding a heat generating module and forming a predetermined inclination, installed in the lower part of the landscaping water, the heat insulating cover part 300 reflecting the heat of the heat generating module to the ground and the temperature of the ground And a control unit 400 equipped with a soil temperature sensor 410a for sensing and controlling the operation of the heat generating module.

2 and 3, the heat generating module 100 emits warm heat by reclaiming trees that grow natively in tropical and subtropical regions, even in the cold or winter season.

In particular, the heat generating module 100 is buried adjacent to the roots of street trees or landscape trees planted on the roadside, and is operated by the control unit 400 when a predetermined temperature is reached.

To this end, the heat generating module 100 further includes a heat generating device 110, a heat insulating layer 120, a metal protection plate 130, and a drain 140.

The heat generating device 110 is formed in a plate shape by embedding an electric heating wire therein, and a fixing frame surrounding the plate is formed.

The heat generating device 110 is located at the bottom of the root of the landscape tree disposed along the roadside and is buried in the ground. In addition, heat is generated at a predetermined temperature by receiving power from the outside.

On the other hand, the heat generating device 110 is also formed of a graphene heating film, it is also preferable to supply heat to the roots of landscape trees by heating through the heat in the ground. For this reason, heat is supplied to the root of the landscape tree to save electricity without consuming additional external power.

Fixing frame 111 is formed of a square frame surrounding the rim of the heat generating device 110, is formed to a predetermined height serves to form the heat generating module 100 as a unit.

Referring to FIG. 3, the insulating layer 120 is provided with a heat insulating material under the heat generating device 110 to protect the loss of heat.

The metal protection plate 130 is positioned on the upper portion of the heat generating device 110 and the lower portion of the heat insulating layer 120, and prevents the heat generating device 110 from being damaged by factors in the external environment or gravel in the ground.

2 and 3, the drainage portion 140 serves to drain the moisture flowing into the ground to the lower portion of the heat generating device 110.

To this end, the drain 140 further includes a drain hole 141, a drain pipe 142, and a bolt 143.

The drain hole 141 penetrates one surface of the heat generating device 110 to form a plurality of holes.

Here, the drain hole 141 is formed to communicate with each other also to the heat insulating layer 120 and the metal protection plate 130 located on the lower and upper portions of the heat generating device 110 so that the drain pipe 142 to be described later can be inserted.

The drain pipe 142 is inserted into the drain hole 141 and is formed in a pipe shape that moves moisture introduced into one surface of the heat generating device 110, and a flange is formed at the top.

Here, the flange is positioned to be exposed on one surface of the metal protection plate 130 located on the top of the heat generating device 110.

The bolt 143 is spirally coupled to the lower portion of the drain pipe 142 and serves to securely place the drain pipe 142 in the heat generating device 110.

1 and 4, the heat insulating reflective film 200 is formed as a side wall surrounding the heat generating module 100 and forming a predetermined slope.

That is, the insulating reflective film 200 prevents heat generated from the heat generating module 100 from spreading to the ground and moves to the ground.

In addition, the insulating reflective film 200 may be spaced apart a predetermined distance along the rim of the heat generating module 100 to form a rectangular shape by arranging sidewalls widening in the upper direction.

And, as shown in Figure 4 (b), a circular side wall surrounding the heat generating module 100 may be formed in a shape in which the diameter increases in the upper direction.

1 and 5, the insulating cover part 300 is installed at the lower part of the landscape tree to serve to reflect the heat of the heat generating module 100 to the ground.

To this end, the thermal insulation cover part 300 further includes a plate part 310, a contact part 320, and a reflective film 330.

The plate portion 310 is a plate-shaped cover that is formed at a lower portion of the landscape tree by forming a hole through the center.

That is, the plate portion 310 is exposed to the ground and is formed in a predetermined area to protect the lower part of the landscape tree.

In particular, the plate portion 310 is formed of a separation portion 340 so that it can be separated on both sides so as to face each other at the bottom of the landscape tree to be combined. here. It is preferable that the member to be joined forms a conventional locking portion.

The contact portion 320 is formed with a wall 321 extending in a vertical direction from a hole formed through the center of the plate portion 310, and a plurality of protrusions 322 in a direction perpendicular to the inside of the wall 321 Is formed.

The wall 321 is formed corresponding to the diameter of the landscape tree so that the inner surface is in close contact with the bottom of the landscape tree. At this time, the wall 321 may be formed of an elastic material or a larger diameter than the diameter of the landscape tree because the diameter of the landscape tree can be increased.

The protrusion 322 protrudes on the inner surface of the wall 321 to form a frictional force on the outer circumferential surface of the landscape tree to increase the adhesion of the wall 321.

The reflective film 330 is provided below the plate portion 310 and serves to reflect heat generated from the heat generating module 100 and moving to the ground.

In particular, the reflective film 330 is preferably formed of aluminum or silver foil to increase the reflectance of heat.

Meanwhile, the thermal insulation cover part 300 may add a configuration of a heat generating device that is electrically operated.

This is to prevent the landscaping of the landscaping in the cold by generating high temperature heat at the roots of the landscaping in parallel with the heat generating module 100 according to the local conditions in winter.

In addition, it is also possible to save power consumption by turning off the operation of the heat generating module 100 in the ground and generating heat in the insulating cover 300 only to the ground.

1 and 6, the control unit 400 is provided with a soil temperature sensor 410a that senses the temperature of the ground and controls the operation of the heat generating module 100.

To this end, the control unit 400 further includes a power supply unit 410, a main circuit breaker 420, a temperature controller 430, and a timer switch 440.

The power supply unit 410 serves to apply electric power to the heat generating module 100 when the predetermined temperature is reached to the soil temperature sensor 410a.

That is, the power supply unit 410 is connected to the heat generating module 100 disposed adjacent to the roots of a plurality of landscape trees formed on the roadside to apply electric power to the outside.

At this time, the signal is received from the soil temperature sensor 410a embedded in the ground to determine whether the power supply unit 410 is operating.

Here, the soil temperature sensor (410a) is preferably to detect the soil temperature near the root of the landscape tree.

Referring to FIG. 6, the main circuit breaker 420 serves to prevent overload of electric power applied to the heat generating module 100.

The temperature controller 430 serves to set the survival temperature of the landscape tree according to the season.

For example, in preparation for the prolongation of the cold in winter, the temperature of the soil layer surrounding the main roots and some roots of landscape trees is constantly raised to a temperature of 5 to 15 degrees, thereby preventing verbs caused by rapid low temperatures.

That is, the temperature controller 430 may be set to increase or decrease the temperature of the heat generating device 110 constituting the heat generating module 100 to increase the temperature of the ground.

In addition, the temperature controller 430, when the temperature of the soil is lowered to 4 degrees Celsius, can work mainly on winter nights to increase the ability to prevent and purify landscape trees due to temperature difference between day and night, and to reduce adaptive power and lower power consumption.

The timer switch 440 controls the operation time of the power supply unit 410 to reduce consumption of power applied to the heat generating module 100 by the operation of the temperature controller 430.

For example, by repeating the operation and stop of the heat generating module 100 at intervals of 1 to 2 hours in the cold of winter, the power consumption is reduced and the required survival temperature of landscape trees is provided. Therefore, it is possible to increase the autogenous power of landscape water by minimizing evaporation of moisture remaining in the ground.

As described above, in the detailed description of the present invention, the preferred embodiments of the present invention have been described, but the exemplary embodiments of the present invention are exemplarily described, and the present invention is not limited thereto. In addition, any person having ordinary knowledge in the technical field to which the present invention pertains is capable of various modifications and imitation without departing from the scope of the technical idea of the present invention.

Therefore, the scope of the present invention is not limited to the above-described embodiments, but may be implemented as various types of embodiments within the scope of the appended claims. And, without departing from the gist of the invention as claimed in the claims, any person with ordinary skill in the art to which the invention pertains is deemed to be within the scope of the claims of the invention to a wide range that can be modified.

10: Landscape native environment system
100: heat generating module
110: heat generating device
111: fixed frame
120: insulating layer
130: metal protection plate
140: drain
141: drainage hole
142: drain pipe
143: bolt
200: insulating reflective film
300: thermal insulation cover
310: plate part
320: close contact
321: Wall
322: incision groove
330: reflective film
400: control unit
410: power supply
410a: Soil temperature sensor
420: main circuit breaker
430: temperature controller
440: timer switch

Claims (6)

It is formed of a plate in which an electric heating wire is buried inside, and a fixing frame surrounding the plate is formed to be buried in the ground. A heat generating module including a metal protection plate located at each of the upper portion of the heat generating device and the lower portion of the heat insulating layer, and a drainage part for draining water flowing into the ground to the lower part of the heat generating device;
An insulating reflective film formed by side walls surrounding the heat generating module and forming a predetermined slope to adjust the slope of the side walls in response to the size of the root of the landscape tree;
It is installed on the lower portion of the landscaping water insulation cover portion for reflecting the heat of the heat generating module to the ground; And
It includes a control unit equipped with a soil temperature sensor for sensing the temperature of the ground to control the operation of the heat generating module,
The drain portion
A drainage hole in which a plurality of holes penetrating the heat generating device and the insulating layer and the metal protection plate and communicating with each other are formed;
A drain pipe formed of a pipe inserted into the drain hole to move moisture flowing into one surface of the metal protection plate located on the top of the heat generating device downward, and having a flange formed on the top of the pipe; And
It is coupled to the lower portion of the drain pipe, characterized in that the drain pipe comprises a bolt that is firmly positioned in the heat generating device
Landscape native environment system.
delete delete According to claim 1,
The heat generating device is formed of a graphene heating film and heats through the underground heat to supply warm heat to the roots of the landscape tree.
Landscape native environment system.
According to claim 1,
The insulating cover part
A plate-shaped plate portion disposed under the landscape tree;
A wall portion extending in a vertical direction from a hole formed through the center of the plate portion, and a plurality of protrusions formed in a direction perpendicular to the inside of the wall portion; And
It is provided on the lower portion of the plate portion further comprises a reflective film that reflects the heat generated from the heat generating module to move to the ground
Landscape native environment system.
According to claim 1,
The control unit
A power supply unit that applies electric power to the heat generating module when it reaches a preset temperature to the soil temperature sensor;
A main circuit breaker to prevent overload of power applied to the heat generating module;
Temperature controller for setting the survival temperature of the landscape tree according to the season; And
Further comprising a timer switch for controlling the operating time of the power supply unit to reduce the consumption of power applied to the heat generating module by the operation of the temperature controller
Landscape native environment system.

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