KR102120707B1 - Far-infrared radiation type heating apparatus for preventing cold weather damage of fruit trees - Google Patents

Abstract

The present invention relates to a long wavelength far-infrared radiation type heating apparatus for preventing a cold damage to fruit trees, which comprises: a base frame disposed on the ground; a first-stage fixing member horizontally disposed on the upper surface of the base frame; a second-stage fixing member placed on the upper side of the first-stage fixing member to be horizontally displaced; an interval maintenance member interposed between the first-stage and second-stage fixing members to be connected, fixed, and vertically disposed and maintaining an interval between the first-stage and second-stage fixing members; two lower far-infrared radiation bodies placed, fixed, and installed at an edge of the upper surface of the first-stage fixing member with an interval of 180° and outwardly radiating far-infrared radiant heat of a long wavelength; and four upper lower far-infrared radiation bodies placed, fixed, and installed at an edge of the upper surface of the second-stage fixing member with intervals of 180°; and outwardly radiating far-infrared radiant heat of a long wavelength. According to the present invention, the far-infrared radiant heat is artificially generated in a wide outdoor field, such as an orchard, to be radiated toward the fruit trees to be heated, thereby effectively reducing the cold damage abnormally occurring in a blooming season of the fruit trees. Moreover, the long wavelength far-infrared radiation type heating apparatus is placed and fixed at a desired place of the orchard to be used or can be used while being moved.

Description

Long-wave infrared radiation heating device for preventing low temperature damage of fruit trees{FAR-INFRARED RADIATION TYPE HEATING APPARATUS FOR PREVENTING COLD WEATHER DAMAGE OF FRUIT TREES}

The present invention relates to a long-wavelength far-infrared radiation type heating device for preventing low-temperature damage of fruit trees, and more specifically, by applying a heat radiation phenomenon rather than a heat transfer method through convection to artificially generate far-infrared rays at a wide outdoor site such as an orchard to generate heat. By providing it to be radiated to the side, it is possible to effectively reduce the low-temperature damage that may occur abnormally in the flowering of the fruit tree, and it is fixed and used in the fruit tree as well as long-wavelength far-infrared radiation for preventing low-temperature damage of the fruit tree. It relates to an expression heating device.

Korea has a climate where you can experience the four seasons of spring, summer, autumn, and winter, and in the season when warm spring passes after winter, fruit trees have a flowering period, and in the spring with such a flowering season, at 20℃ Abnormal low-temperature phenomena such as the cold spring of a flower may occur, such as the temperature of a sudden drop in the temperature after continuing to keep the warm temperature near.

As described above, suddenly an abnormal low temperature phenomenon occurs during the flowering period of the fruit tree, and usually, if it lasts for 3 to 5 days or more, low temperature damage occurs in the fruit tree.

For example, as of 2018, pears were the most damaged in fruit trees in bloom in Korea, peaches had the largest damage in early-growing species (nectarine), and apples had low temperatures (Geochang, Hamyang, Muju). , Longevity), and other fruit trees, such as plums (Jeonbuk, Gyeongbuk), cherries, and apricots (Gyeongbuk), have been reported to have suffered considerable damage from nuclear fruit farms.

Accordingly, not only is it necessary to minimize damage to fruit trees through manual production, prior distribution and education on crop management tips, but also measures are being taken to implement effective technologies to reduce low-temperature damage among flowering trees in Korea. It is being used.

Increasingly, as a method to prevent low-temperature damage among the flowering trees of fruit trees, a method of raising air temperature in the orchard by making air flow by blowing warm air at the top of the temperature inversion layer downward by installing 5 to 6 air-conditioning fans per ha Phosphorus fan treatment method, blower method that directly blows air heated by a heating wire, micro-spray treatment method that uses latent heat released when water becomes ice, and combustion method that burns rice husk or rice straw, And the use of an anti-frost agent that is treated with chemical control.

However, the air-conditioning fan treatment method and the fine sprinkling treatment method provide a temperature increase effect that can increase the degree of 2 to 3°C relative to other methods, but the air-conditioning fan treatment method has an initial installation cost compared to other methods. There is a disadvantage that it is more than 3 times higher, and the micro-spraying method requires a lot of water of 13.3 tons per hour, and also has a disadvantage that it can cause a great damage to flowers in contact with water when stopping spraying before sunrise.

It is known that the blowing method can be expected to only increase the temperature of about 1~2℃ within a 25m radius and 0.2ha area, and it is effective to install and use it in some areas with severe frost in the orchard, not the entire orchard.

Since the combustion method requires the preparation of a combustor in advance, the work is cumbersome, and after ignition, not only does it take a lot of effort to manage the combustor, but it also has a disadvantage that it can only manage about 10~15a per person. Although it is inexpensive compared to the method, it has been found that it is difficult to meet the exact control timing, and it cannot guarantee the effect, and excessive use of an anti-frost agent of a specific component may cause malformation of the fruity form.

On the other hand, when looking at the prior art documents related to the measures to prevent low-temperature damage of conventional fruit trees, the technical content of the proposed cold-water prevention device using hot air is disclosed in Korean Utility Model No. 20-0393127, and Korean Patent Publication No. 10-2013 -0046912 discloses a technology content that proposes an anti-cold agent for fruit trees and fruits and vegetables, and these prior arts have special differences in terms of composition and effect from the technology of the present invention described below.

Republic of Korea Utility Model Publication No. 20-0393127 Republic of Korea Patent Publication No. 10-2013-0046912

The present invention is to solve the above-mentioned problems and to solve this problem, by applying a heat radiation phenomenon, rather than a heat transfer method through convection, to generate far-infrared radiation heat artificially in a wide outdoor site such as an orchard, so that it can radiate to the fruit tree side, which is a heating target. By providing it, it is possible to very effectively reduce low-temperature damage that may occur abnormally in the flowering of fruit trees, and provides a long-wavelength far-infrared radiation heating device for preventing low-temperature damage of fruit trees that is fixed and used in fruit trees and enables mobile use. There is a purpose.

The present invention is to prevent low-temperature damage of fruit trees that can radiate far-infrared radiation of the long wavelength band toward the fruit tree and heat it to the inside, not the surface of the fruit tree, and improve the efficiency for reducing low-temperature damage among the flowering trees of the fruit tree. The purpose is to provide a long wavelength far infrared radiation heating device.

The present invention is installed to radiate far-infrared radiation in a 360-degree direction so as to increase the radiation efficiency and heating efficiency, and by providing an angle control, the radiation angle is adjusted according to the growth conditions and weather conditions of the fruit tree. An object of the present invention is to provide a long-wavelength far-infrared radiation heating device for preventing low-temperature damage of fruit trees that can be used while going.

A long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees for achieving the above object, a base frame disposed on the ground; A first stage fixing member horizontally disposed on the upper surface of the base frame; A two-stage fixing member positioned horizontally above the first-stage fixing member; A gap-holding member interposed between the first-stage fixing member and the second-stage fixing member to be fixed and vertically connected to maintain a gap between the first-stage fixing member and the second-stage fixing member; A lower far-infrared emitter that is fixedly installed at an edge of the upper surface of the first-stage fixing member, and is provided at two 180-degree intervals to radiate far-infrared radiation of a long wavelength in an outward direction; It is characterized in that it comprises a; located at the edge of the upper surface of the two-stage fixing member, fixedly installed, and installed at four intervals of 90 degrees, and provided to radiate far-infrared radiation heat of a long wavelength in an outward direction.

Here, the first stage fixing member is provided as a square frame structure and fixedly installed at a forward placement angle, and the two lower far-infrared radiators are disposed relative to each other to be fixedly installed on the left and right sides of the first stage fixing member; The two-stage fixing member is provided with a square-shaped frame structure, and is fixedly installed at a rhombic arrangement angle based on the forward arrangement of the first-stage fixing member, and the four upper far-infrared radiators are arranged in a rhombus-shaped two-stage fixing member side. It can be configured to radiate far-infrared radiation in a 360-degree direction by being fixed to the side.

Here, each of the far-infrared emitters comprises: a far-infrared heating unit made of a bar-shaped far-infrared lamp; A reflector that induces radiation to be radiated toward the front with respect to the far infrared radiation radiated from the far infrared heating unit; It may be provided on the front portion of the far infrared lamp, the temperature sensor for controlling the far infrared heating unit.

Here, each of the far-infrared emitters, by using the connection to control the set temperature of the temperature sensor side, for the efficiency of the control SCR controller for performing an AC phase control; may further have a configuration further comprising.

Here, each of the far-infrared emitters can be installed to be adjustable in the vertical direction through a configuration combined with the angle adjusting means.

Here, the angle adjusting means is located on the upper surfaces of the first and second fixed members, and is a paired structure disposed on the left and right sides of each fixed and each far-infrared radiator, and angle-adjusting holes at regular intervals along the outer edge. Fan-shaped angle control plate formed; An angle fixing pin inserted into an angle adjusting hole of the angle adjusting plate and having a fixing function to maintain an angle adjusting state; It is provided with a protrusion on the inner surface of the angle adjustment plate can have a configuration including; a hinge shaft holder having a hinge shaft insertion hole for use in hinge coupling with each of the far-infrared emitter side hinge shaft.

Here, each of the far-infrared emitters is located on the upper surfaces of the first-stage fixing member and the second-stage fixing member to be rotatably installed in the vertical direction by hinge engagement at the lower end, respectively, and the first-stage fixing member and the second-stage fixing member Fixing bolts for fixing the chains or wires on the upper surface of each are fixedly installed, but one end of the angle adjustment wire of the chain or wire is fixed to the fixing bolt, and the other end is fixed to the hook portion fixed to the inner upper end of each far infrared emitter. It can be configured to be able to adjust the angle in the vertical direction for each far-infrared emitter correspondingly connected by adjusting the length of each angle adjusting wire.

Here, the temperature sensor may be configured as a K-type thermocouple to provide ease of installation and connection with a far-infrared heating unit made of the far-infrared lamp, as well as to increase temperature sensing efficiency.

Here, the base frame, a horizontal frame disposed on the ground; A vertical frame extending from an upper surface of the horizontal frame and vertically disposed and spaced at four directions; It is possible to have a configuration including; a movable wheel fixedly installed on the lower surface of the horizontal frame.

According to the present invention, far-infrared radiation heat is artificially generated from a wide outdoor site, such as an orchard, and radiated to the fruit tree, which is a heating target, to effectively reduce the low-temperature damage that may occur abnormally in the flowering of the fruit tree, and to prevent low-temperature damage of the fruit tree It is possible to achieve a useful effect that can be used while moving as well as using a long-wavelength far-infrared radiation heating device fixedly placed at a desired place in the fruit tree.

The present invention can radiate far-infrared radiation in the long wavelength band toward the fruit tree, so that it can be heated to the inside, not the surface of the fruit tree, thereby improving the efficiency for reducing low-temperature damage among the flowering trees of the fruit tree, and rotating the far-infrared radiation heat in the 360-degree direction. With the structure arrangement that can be radiated, it is possible to increase the radiation efficiency and heating efficiency, and since the angle can be adjusted, it is possible to achieve useful effects that can be used while adjusting the radiation angle if necessary according to the growth condition of the fruit tree and weather conditions. .

According to the present invention, it is possible to provide a new type of heating device that can replace existing methods that are inefficient or have little effect, maximize the space utilization of the orchard, and install the heating device at the required loading position in the orchard space. Not only can it be used, it can also achieve useful effects that can broaden the scope of application, such as during flowering, as well as being easily applied to other farms that require heating or low temperature for crops during agricultural work.

1 is a perspective view showing a long-wavelength far infrared radiation heating apparatus for preventing low temperature damage of fruit trees according to an embodiment of the present invention.
Figure 2 is a front view showing a long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
3 is a plan view showing a long-wavelength far infrared radiation heating apparatus for preventing low temperature damage of fruit trees according to an embodiment of the present invention.
Figure 4 is a perspective view showing a main portion for explaining the angle adjustment means in the long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
5 is an exemplary view showing a far-infrared emitter side angle adjustment state in a long-wavelength far-infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
6 is another exemplary view showing a far-infrared radiator side angle adjustment structure in a long-wavelength far-infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
7 is a block diagram showing the far-infrared heating unit of the far-infrared radiator in the long-wavelength far-infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
8 is a view showing a configuration including a moving wheel in the long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
9 is a view showing a use state of a long-wavelength far-infrared radiation heating apparatus for preventing low-temperature damage to fruit trees according to an embodiment of the present invention, which is disposed near fruit trees of an orchard.
FIG. 10 is an exemplary view and installation state photograph showing an experimental state for a field test for a long-wavelength far-infrared radiation heating device for preventing low-temperature damage of fruit trees according to an embodiment of the present invention.
11 is data showing experimental results of a field test test for a long-wavelength far-infrared radiation heating device for preventing low-temperature damage of fruit trees 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.

Terms used in the present invention are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of the user or operator, and thus, definitions of these terms are consistent with the technical matters of the present invention. And should be interpreted as a concept.

1 to 9 of the accompanying drawings are drawings for explaining a long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to the present invention.

The long-wavelength far-infrared radiation heating apparatus 100 for preventing low-temperature damage of fruit trees according to an embodiment of the present invention, as shown in FIGS. 1 to 9, the base frame 110 and the base frame 110 disposed on the ground The first-stage fixing member 120 horizontally disposed on the upper surface, the second-stage fixing member 130 horizontally disposed above the first-stage fixing member 120, and the first-stage fixing member 120 and the second stage Interposed between the fixing member 130, the connection is fixed and vertically arranged to maintain the gap between the first-stage fixing member and the second-stage fixing member 140, and the upper surface of the first-stage fixing member 120 Located at the edge and fixedly installed and installed at intervals of 180 degrees, the lower far-infrared radiator 150 provided to radiate far-infrared radiation heat of a long wavelength in an outward direction, and located at the edge of the upper surface of the two-stage fixing member 130 It is fixedly installed and is installed at four intervals of 90 degrees, but consists of a configuration including an upper far-infrared emitter 160 provided to radiate far-infrared radiation of a long wavelength in an outward direction.

The base frame 110 has a function as a support for supporting the far-infrared radiation heating device 100 as a whole, and also serves to position the far-infrared radiators 150 and 160 at a certain height.

The base frame 110 is placed on the ground of the orchard, horizontal frame 111 to exhibit a function of stably supporting, and extended from the upper surface of the horizontal frame 111 is positioned vertically and in all directions (四方) It can be composed of a vertical frame 112 having four vertical posts spaced apart.

At this time, the base frame 110 may have a configuration for fixedly installing the moving wheel 113 on the lower surface of the horizontal frame 111, and may be configured to have ease according to the movement arrangement.

Here, the moving wheel 113 is preferably applied to the wheel with a locking function for safety during fixed use.

The first stage fixing member 120 is a support for installing the lower far-infrared radiator 150, and is provided as a square frame structure to be fixedly installed at a forward placement angle.

The second-stage fixing member 130 is a support for installing the upper far-infrared radiator 160, and is provided as a square frame structure, and fixed at a rhombic arrangement angle based on the forward arrangement of the first-stage fixing member 120. Install it.

Here, the fixed installation at a rhombic arrangement angle based on the forward arrangement of the first-stage fixing member 120 with respect to the second-stage fixing member 130 means that the far-infrared radiant heat is radiated upon installation of each far-infrared radiator 150, 160. It is a structural arrangement design for installation so that it can be easily radiated in the 360 degree direction.

The two lower far-infrared emitters 150 are installed relative to the left and right sides of the first-stage fixing member 120 by arranging them relative to each other based on the illustrated drawing state.

The four upper far-infrared emitters 160 are fixedly installed to be located at the edges of the four sides of the two-stage fixing member 130 arranged in a rhombus shape.

Each of the far-infrared emitters 150 and 160 is configured to effectively prevent low-temperature damage that may occur abnormally in the flowering of fruit trees by heating the fruit trees by radiating far-infrared radiation heat, which is a long wavelength band, toward fruit trees.

To this end, each of the far infrared emitters 150 and 160 includes a far-infrared heating unit 151 and 161 formed by connecting and assembling a bar-shaped far infrared lamp L, and a long wavelength band radiated from the far infrared heating unit Reflectors 152 and 162 for inducing radiation to be radiated toward the front with respect to the far-infrared radiation, and installed on the front side of the far-infrared lamp on the far-infrared lamp side for use in controlling the temperature of the far-infrared heater side It is possible to have a configuration including the temperature sensor 153, 163.

Each of the far-infrared emitters 150 and 160 is used to connect the temperature sensors 153 and 163 to control the set temperature, and the SCR controller 154 for performing AC phase control for efficiency of control ( 164) is further preferred.

Here, the temperature sensors 153 and 163 provide K-type thermocouples to provide ease of installation and connection with the far-infrared heating units 151 and 161 made of the far-infrared lamp. It is desirable to construct.

In addition, each of the far-infrared emitters 150 and 160 may be installed to be capable of adjusting the angle in the vertical direction in combination with the angle adjusting means 170.

To this end, each of the angle adjusting means 170 is located on the upper surfaces of the first-stage fixing member 120 and the second-stage fixing member 130 to be fixedly coupled to each other and disposed on the left and right sides of each far-infrared radiator 150 and 160 As a paired structure, the fan-shaped angle adjusting plate 171 having an angle adjusting hole 172 formed at regular intervals along the outer edge and an angle adjusting hole 172 of the angle adjusting plate 171 are inserted and disposed to adjust the angle. An angle fixing pin 173, which functions to fix the retainer, and a hinge shaft for protruding on the inner surface of the angle adjusting plate 171, for use in hinge coupling with each of the far infrared emitter side hinge shafts 150A and 160A It is possible to have a configuration including a hinge shaft holder 174 having an insertion hole.

Here, pin fixing holes 155 and 165 for inserting and fixing the angular fixing pins 173 are formed on the side of each far infrared ray emitter 150 and 160 in a corresponding size.

In addition, each of the far-infrared emitters 150 and 160 is a different type of implementation from the method of using the angle adjusting means 170, the upper surface of the first-stage fixing member 120 and the second-stage fixing member 130. Positioned to be rotatable in the up and down direction by hinge engagement at the lower end of each, and fixing bolts 181 for fixing the chain or wire to the upper surfaces of the first and second stage fixing members 120 and 130 respectively. To the fixed installation, the fixed bolt 181 is connected to one end of the angle adjustment wire 182 of the chain or wire, and the other end is attached to the hook portion 183 fixed to the inner upper end of each far infrared emitter 150, 160 It is also possible to have a connection fixing configuration.

Through this configuration, each of the far infrared emitters 150 and 160 is connected to each of the far infrared emitters 150 and 160 by adjusting and fixing the connected length of each angle adjusting wire 182 that is fixedly connected to each of the far infrared emitters 150 and 160. It can be used by adjusting the angle in the vertical direction.

On the other hand, Figures 10 and 11 is a view showing the state of the test and the test results installed in the field for a long-wavelength far infrared radiation heating apparatus 100 for preventing low-temperature damage of fruit trees according to the present invention having the above-described configuration.

Here, a long-wavelength far-infrared radiation heating apparatus 100 for preventing low-temperature damage of fruit trees according to the present invention is installed in the field, and tested for temperature fluctuations by distance, and a long-wavelength far-infrared radiation heating apparatus for preventing low-temperature damage of fruit trees according to the present invention For (100), each far-infrared emitter 150, 160 was connected to nine far-infrared lamps with a capacity of 1 kw and was manufactured and used with a capacity of 9 kw, and the upper far-infrared radiator 160 had a tilt angle of 57°. And the lower far-infrared emitter 150 was disposed at an inclination angle of 63° and tested at ambient temperature below zero at dawn.

As a result of the test according to the installation, the temperature of the fruit tree and the soil was clearly increased, and the effective radiation distance to prevent the low temperature damage of the fruit tree was analyzed to be about 10 m under the above manufacturing conditions.

Accordingly, through the long-wavelength far-infrared radiation type heating device 100 for preventing low-temperature damage of fruit trees according to the present invention having the above-described configuration, far-infrared radiation heat is artificially generated from a wide outdoor site such as an orchard and radiated to the fruit tree, which is a heating target. It can provide an advantage that can effectively reduce the low-temperature damage that can occur abnormally during flowering.

The embodiments described above are merely for explaining preferred embodiments of the present invention, and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the technical spirit and claims of the present invention. It will be said that this can be made, which will fall within the technical scope of the present invention.

110: base frame 120: 1-stage fixing member
130: two-stage fixing member 140: spacing maintenance member
150: lower far-infrared emitter 160: upper far-infrared emitter
170: angle adjustment means

Claims (9)

A base frame disposed on the ground;
A first stage fixing member horizontally disposed on the upper surface of the base frame;
A two-stage fixing member positioned horizontally above the first-stage fixing member;
A gap-holding member interposed between the first-stage fixing member and the second-stage fixing member to be fixed and vertically connected to maintain a gap between the first-stage fixing member and the second-stage fixing member;
A lower far-infrared emitter that is fixedly installed at an edge of the upper surface of the first-stage fixing member, and is provided at two 180-degree intervals to radiate far-infrared radiation of a long wavelength in an outward direction; And
An upper far-infrared emitter positioned at the edge of the upper surface of the two-stage fixing member and fixedly installed, and provided with four at 90-degree intervals to radiate far-infrared radiation of a long wavelength in an outward direction; Including,
The first stage fixing member is provided as a square frame structure and fixedly installed at a forward placement angle, and the two lower far infrared radiators are disposed relative to each other to be fixedly installed on the left and right sides of the first stage fixing member;
The two-stage fixing member is provided with a square-shaped frame structure, and is fixedly installed at a rhombic arrangement angle based on the forward arrangement of the first-stage fixing member, and the four upper far-infrared radiators are arranged in a rhombus-shaped two-stage fixing member. It is configured to radiate far-infrared radiation in a 360-degree direction by fixing it on the side,
Each of the far-infrared emitters includes: a far-infrared ray heating unit formed of a bar-shaped far-infrared lamp; A reflector that induces radiation to be radiated toward the front with respect to the far infrared radiation radiated from the far infrared heating unit; And a temperature sensor installed on a front portion of the far infrared lamp to control the far infrared heating unit. Including,
Each of the far-infrared emitters, which is used in connection to control the set temperature of the temperature sensor side, an SCR controller for performing AC phase control for efficiency of control; While further comprising, the temperature sensor is configured as a K-type thermocouple to provide ease of installation and connection with a far-infrared heating unit made of the far-infrared lamp, as well as to increase temperature sensing efficiency,
The far-infrared emitters are located on the upper surfaces of the first-stage fixing member and the second-stage fixing member so as to be able to adjust the angle in the vertical direction, and are respectively installed to be rotatable in the vertical direction by the lower end side hinge coupling. A fixing bolt for fixing the chain as an angle adjusting wire is fixedly installed on the upper surface of the two-stage fixing member, and one end of the chain is connected to the fixing bolt, and the other end is connected to a hook fixed to the inner upper end of each far infrared emitter. The long-wavelength far-infrared radiation type heating device for preventing low temperature damage of fruit trees, characterized in that it is configured to adjust the angle in the vertical direction with respect to each far-infrared emitter correspondingly connected by adjusting the length of each chain.
According to claim 1,
The base frame,
A horizontal frame disposed on the ground;
A vertical frame extending from an upper surface of the horizontal frame and vertically arranged and spaced apart in four directions;
A movable wheel fixedly installed on the lower surface of the horizontal frame; Long-wavelength far infrared radiation heating apparatus for preventing low-temperature damage of fruit trees comprising a. delete delete delete delete delete delete delete

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