KR102086330B1 - System for measuring thermal property of greenhouse material - Google Patents

Abstract

In one embodiment, a system for measuring thermal properties of greenhouse materials includes a frame configured to be mounted with greenhouse materials; Net radiation amount measuring unit for measuring the net radiation amount in the upper and lower parts of the greenhouse material; And a temperature measuring unit disposed above or below the greenhouse material to measure an upper temperature or a lower temperature of the greenhouse material, wherein the greenhouse material includes a heat insulating material, a heat insulating material, or a light shielding material. Greenhouse material may be provided detachably with respect to the frame.

Description

System for measuring thermal properties of greenhouse materials {SYSTEM FOR MEASURING THERMAL PROPERTY OF GREENHOUSE MATERIAL}

The present invention relates to a system for measuring thermal properties of greenhouse materials.

The main purpose of the coating in the greenhouse is to raise the temperature of the internal air by solar radiation entering the greenhouse during the day. The most basic property of the coating material used for this purpose is light transmission and thermal insulation. However, these two conditions are mutually opposite physical properties, so it is quite difficult to satisfy them at the same time. Therefore, the development of a coating material and a coating method which is as excellent as possible light transmittance and excellent heat insulation effect is continuously required.

At this time, the long-wave radiation characteristics of the greenhouse material, for example, reflectance, emissivity (absorption rate), transmittance is an essential property for analyzing the thermal insulation performance of the greenhouse.

For example, prior art document JP2004-257898, filed on September 6, 2004, discloses a method and a test apparatus for inspecting insulation performance of insulation.

The background art described above is possessed or acquired by the inventors in the process of deriving the present invention, and is not necessarily a known technology disclosed to the public before the application of the present invention.

An object according to an embodiment is to measure the long-wave radiation characteristics (for example, reflectance, absorbance, transmittance) of the greenhouse material (insulation material, insulation or light-shielding material), to quantitatively present the thermal insulation performance of the greenhouse material It is to provide a system for measuring the thermal properties of greenhouse materials.

An object according to an embodiment is to provide a thermal property measurement system for greenhouse materials that can measure or compare the thermal insulation performance of the greenhouse materials by measuring the long-wave radiation characteristics of all greenhouse materials that are distributed in Korea will be.

An object according to an embodiment is to provide a system for measuring the thermal properties of a greenhouse material that can be installed in the upper and lower portions of the greenhouse material by the net radiation sensor can easily measure the long-wave radiation characteristics of the greenhouse material indoors or outdoors.

An object according to an embodiment is to provide a system for measuring the thermal properties of a greenhouse material that can be easily attached to the greenhouse material on the frame to measure the long-wave radiation characteristics according to the combination of various greenhouse materials.

According to an embodiment of the present invention, there is provided a system for measuring thermal properties of greenhouse materials, the frame configured to be mounted with greenhouse materials; Net radiation amount measuring unit for measuring the net radiation amount in the upper and lower parts of the greenhouse material; And a temperature measuring unit disposed above or below the greenhouse material to measure an upper temperature or a lower temperature of the greenhouse material, wherein the greenhouse material includes a heat insulating material, a heat insulating material, or a light shielding material. Greenhouse material may be provided detachably with respect to the frame.

According to one side, the net radiation amount measuring unit, the first net radiation amount sensor disposed on the greenhouse material for measuring the net radiation amount; And a second net radiation amount sensor disposed under the greenhouse material to measure a net radiation amount, wherein the second net radiation amount sensor measures the net radiation amount based on the net radiation amount measured by the first net radiation amount sensor and the second net radiation amount sensor, respectively. Thermal properties of the material can be calculated.

According to one side, the net radiation amount measuring unit further comprises a fixing part for holding the upper and lower parts of the greenhouse material, the fixing part is provided in the '' 'cross-sectional shape, the first net at the upper end of the fixing part The radiation amount sensor is mounted, and the second net radiation amount sensor is mounted at the lower end of the fixing part, and the greenhouse material is disposed at the center of the side of the fixing part, so that the first net radiation sensor and The distance between the second net radiation sensor may be the same.

According to one side, the black body is provided on the frame, and implements a black body surface on the lower portion of the greenhouse material; further comprising, the black body implementation is provided with a black cloth mounted to the frame, the temperature measurement The unit further measures the temperature of the blackbody implementation, the temperature measuring unit, a first temperature sensor for measuring the upper temperature of the greenhouse material; And a second temperature sensor configured to measure a temperature of the blackbody implementing unit under the greenhouse material.

According to one side, a calculation unit for calculating the thermal characteristics of the greenhouse material based on the values measured in the net radiation measurement unit and the temperature measuring unit; further comprising, the calculation unit measured by the first temperature sensor The perforated radiant energy is calculated from the upper temperature of the greenhouse material, the radiant energy of the blackbody implement is calculated from the temperature of the blackbody implementer measured by the second temperature sensor, and the greenhouse use measured by the net radiation measuring unit. Radiation energy of the greenhouse material is calculated from the difference in the net radiation amount of the upper and lower parts of the material, and in the calculation unit, the perforated radiation energy, the radiation energy of the blackbody realization unit, the radiation energy of the greenhouse material, and the net radiation measurement unit A relational equation for the net radiation quantity measured on top of the greenhouse material and the perforated radiant energy, phase The reflectance and transmittance of the greenhouse material may be calculated from a relational expression for the radiation energy of the blackbody implementing unit, the radiation energy of the greenhouse material, and the net radiation amount under the greenhouse material measured by the net radiation measurement unit.

According to an embodiment of the present invention, there is provided a system for measuring thermal properties of greenhouse materials, the frame configured to be mounted with greenhouse materials; A black body implementing unit provided in the frame to implement a black body surface under the greenhouse material; A net radiation measuring unit including a first net radiation sensor for measuring a net radiation amount at an upper portion of the greenhouse material and a second net radiation sensor for measuring a net radiation amount at a lower portion of the greenhouse material; A temperature measuring unit including a first temperature sensor measuring an upper temperature of the greenhouse material and a second temperature sensor measuring a temperature of the blackbody implementing unit; And a calculation unit calculating a thermal characteristic of the greenhouse material based on the values measured by the net radiation measurement unit and the temperature measuring unit, wherein the thermal characteristics of the greenhouse material are reflectance and transmittance of the greenhouse material. Or emissivity.

According to one side, the calculation unit in the perforated radiant energy is calculated from the upper temperature of the greenhouse material measured by the first temperature sensor, the radiation of the blackbody implementation from the temperature of the blackbody implementation measured by the second temperature sensor Energy is calculated, and the radiant energy of the greenhouse material is calculated from the difference between the net radiation measured by the first net radiation sensor and the net radiation measured by the second net radiation sensor. The relationship between the radiation energy of the blackbody realization unit, the radiation energy of the greenhouse material and the net radiation amount on the upper greenhouse material measured by the first net radiation sensor, and the perforated radiation energy, the radiation energy of the blackbody implementation unit, Under the greenhouse material measured by the radiation energy of the greenhouse material and the second net radiation sensor Is the reflectance and transmittance of the material for greenhouses calculated from the relational expression for the net radiation, the operation unit is in the emissivity of the material from the Greenhouse equation for the reflectivity, the transmissivity and emissivity of the material for greenhouses can be calculated.

According to one side, the calculation unit calculates the puncture radiation energy by the following equation,

In this case, R ₁ is the puncture radiant energy, σ is the Stefan Boltzmann constant, T _S is the puncture temperature, T _a is the temperature measured by the first temperature sensor.

According to one side, the calculation unit in the radiation energy of the blackbody implementation is further calculated by the following equations,

In this case, E _w is the radiation energy of the black body implementation, ε _w is the emissivity of the black body implementation, T _w is the temperature measured by the second temperature sensor, ρ _w is the reflectance of the black body implementation.

According to one side, the calculation unit further calculates the radiant energy of the greenhouse material by the following equation,

는 상기 제1 순복사량 센서에서 측정된 온실용 자재 상부에서의 순복사량이고,

는 상기 제2 순복사량 센서에서 측정된 온실용 자재 하부에서의 순복사량이고, R₁은 상기 천공 복사에너지이고, R₂는 상기 온실용 자재 상부에서의 상향 복사에너지이고, R₃은 상기 온실용 자재 하부에서의 하향 복사에너지이고, R₄는 상기 온실용 자재 하부에서의 상향 복사에너지이다.In this case, E _n is the radiation energy of the greenhouse material,

Is the net radiation amount on top of the greenhouse material measured by the first net radiation amount sensor,

Is the net radiation amount under the greenhouse material measured by the second net radiation sensor, R ₁ is the perforated radiation energy, R ₂ is the upward radiation energy on the greenhouse material top, R ₃ is for the greenhouse It is the downward radiant energy under the material, and R ₄ is the upward radiant energy under the greenhouse material.

According to one side, the calculation unit calculates the reflectance, transmittance and emissivity of the greenhouse material by the following relations,

In this case, ρ _n is the reflectance of the greenhouse material, ε _n is the emissivity of the greenhouse material, and τ _n is the transmittance of the greenhouse material.

According to the thermal property measurement system of the greenhouse material according to an embodiment, by measuring the long-wave radiation characteristics (for example, reflectance, absorption, transmittance) of the greenhouse material (insulation material, insulation or light shielding material), Thermal insulation performance can be quantitatively presented.

According to the thermal property measurement system of the greenhouse material according to an embodiment, it is possible to analyze or compare the thermal insulation performance according to the type of greenhouse material by measuring the long-wave radiation characteristics of all the greenhouse materials spread in the country.

According to the thermal characteristic measurement system of the greenhouse material according to an embodiment, the long-wave radiation characteristics of the greenhouse material can be easily measured indoors or outdoors by installing a net radiation sensor on the upper and lower portions of the greenhouse material.

According to the thermal property measurement system of the greenhouse material according to an embodiment, the greenhouse material is detachably attached to the frame to easily measure the long-wave radiation characteristics according to the combination of the various greenhouse materials.

1 illustrates a configuration of a system for measuring thermal properties of greenhouse materials according to an embodiment.
2 schematically illustrates a system for measuring thermal characteristics of a greenhouse material according to an embodiment.

Hereinafter, embodiments will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiment, when it is determined that the detailed description of the related well-known configuration or function interferes with the understanding of the embodiment, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that may be "connected", "coupled" or "connected".

Components included in any one embodiment and components including common functions will be described using the same names in other embodiments. Unless stated to the contrary, the description in any one embodiment may be applied to other embodiments, and detailed descriptions thereof will be omitted in the overlapping range.

1 illustrates a configuration of a thermal property measurement system of a greenhouse material according to an embodiment, and FIG. 2 schematically illustrates a thermal property measurement system of a greenhouse material according to an embodiment.

1 or 2, the thermal property measurement system 10 for a greenhouse material according to an embodiment includes a frame 100, a net radiation measurement unit 200, a fixing unit 300, a black body implementing unit 400 , The temperature measuring unit 500 and the calculating unit 600 may be included.

The frame 100 may be configured to mount the greenhouse material (S).

At this time, the greenhouse material (S) may include a heat insulating material, a heat insulating material or a light shielding material provided in a planar shape.

Specifically, the greenhouse material (S) may be any one of the heat insulating material, the heat insulating material and the light shielding material, or may be a combination of at least two of the heat insulating material, the heat insulating material and the light blocking material.

In particular, since the greenhouse material S is detachably provided in the frame 100, thermal characteristics of the greenhouse material S in various combinations can be measured.

In addition, the frame 100 may be provided so that the greenhouse material S is maintained in a state spaced upwardly from the black body implementing unit 400, and the frame between the greenhouse material S and the black body implementing unit 400. The side of the 100 may be open to the outside.

On the other hand, the thermal properties of the greenhouse material (S) can be performed outdoors or indoors, the frame 100 may also be arranged outdoors or indoors.

For example, when the frame 100 is disposed outdoors, the perforated radiant energy of the night may be incident on the greenhouse material S.

On the other hand, when the frame 100 is disposed in the room, a perforated radiation implementation (not shown) is separately disposed on the upper portion of the frame 100, the perforated radiation energy by the perforated radiation implementation in the greenhouse material (S) Can be incident.

As described above, the net radiation amount measuring unit 200 may be disposed to be spaced apart from the greenhouse material S mounted on the frame 100.

The net radiation measurement unit 200 may measure the net radiation amount in the upper and lower portions of the greenhouse material (S).

Specifically, the net radiation amount measuring unit 200 may include a first net radiation amount sensor 210 and a second net radiation amount sensor 220.

In this case, the first net radiation sensor 210 and the second net radiation sensor 220 may be provided as an instrument for measuring the radiation energy of a wide wavelength range of 300-10,000 nm including short wave radiation and long wave radiation.

The first net radiation sensor 210 is disposed on the upper portion of the greenhouse material (S), the net radiation amount at the top of the greenhouse material (S), that is, the perforated radiant energy and upward radiation at the top of the greenhouse material (S). The difference in energy can be measured.

In this case, the first net radiation sensor 210 may be spaced apart from the upper surface of the greenhouse material S at a vertical distance from the center of the greenhouse material S by a predetermined distance.

The second net radiation sensor 220 is disposed under the greenhouse material (S) so that the net radiation amount at the bottom of the greenhouse material (S), that is, the upward radiation energy and the downward radiation at the bottom of the greenhouse material (S). The difference in energy can be measured.

In this case, the second net radiation sensor 220 may be disposed to face each other with the first net radiation sensor 210 and the greenhouse material S interposed therebetween, and in a vertical lower portion from the center of the greenhouse material S. It may be spaced apart from the lower surface of the greenhouse material (S) by a predetermined distance.

For example, the distance that the first net radiation sensor 210 is spaced apart from the top surface of the greenhouse material S and the distance that the second net radiation sensor 220 is spaced apart from the bottom surface of the greenhouse material S may be the same. Can be.

In addition, the net radiation amount measured by the net radiation measurement unit 200, specifically, the net radiation amount measured by the first net radiation sensor 210 and the second net radiation sensor 220 may be transmitted to the calculation unit 600. Afterwards, the calculation unit 600 may be used to calculate the thermal characteristics of the greenhouse material (S). This is described in detail below.

On the other hand, in order to maintain the above-described net radiation measurement unit 200 in the upper and lower portions of the greenhouse material (S) may be mounted to the fixing part 300 on one side of the frame (100).

The fixing part 300 may be provided in the '' 'cross-sectional shape.

In detail, the first net radiation sensor 210 may be mounted at the upper end of the fixing part 300, and the second net radiation sensor 220 may be mounted at the lower end of the fixing part 300.

In addition, the greenhouse material S is disposed at the center of the side of the fixing part 300, and thus, between the first net radiation sensor 210 and the second net radiation sensor 220 from the greenhouse material S, as described above. The distances can be the same.

However, the shape of the fixing part 300 is not limited thereto, and any one can be maintained as long as the first net radiation sensor 210 and the second net radiation sensor 220 can be maintained at the upper and lower portions of the greenhouse material S. Do.

Meanwhile, the black body implementing unit 400 may be disposed below the greenhouse material S in the frame 100.

The black body implementing unit 400 is to implement a black body surface that completely absorbs all radiation, for example, the black body implementing unit 400 may be provided with a black cloth, the black cloth may be mounted on the frame 100. have.

Specifically, some of the perforated radiant energy incident on the greenhouse material (S) is reflected from the greenhouse material (S), the remaining part of the perforated radiant energy penetrates the greenhouse material (S) to implement the blackbody implementation 400 Can be absorbed.

At this time, the configuration of the black body implementation unit 400 is not limited thereto, and any one can be implemented if the black body surface can be implemented.

On the other hand, the temperature measuring unit 500 may be disposed on the upper and lower portions of the greenhouse material (S).

The temperature measuring unit 500 may include a first temperature sensor 510 for measuring the upper temperature of the greenhouse material (S).

As described above, when the frame 100 is disposed outdoors, the first temperature sensor 510 may measure the outside temperature, and when the frame 100 is disposed indoors, the first temperature sensor 510 may It is possible to measure the temperature between the greenhouse material (S) and the perforated radiation implementation.

In this case, the upper temperature of the greenhouse material S measured by the first temperature sensor 510 may be transmitted to the calculator 600, and may be used to calculate the puncture radiant energy in the calculator 600. This is described in detail below.

In addition, the temperature measuring unit 500 may further include a second temperature sensor 520 for measuring the temperature of the black body implementing unit 400.

The second temperature sensor 520 may be provided as, for example, a thermocouple, and is mounted on the surface of the black body implementing unit 400, for example, the surface of a black cloth, and thus, the black body implementing unit 400. Surface temperature, for example the surface temperature of a black cloth, can be measured.

In this case, the temperature of the black body implementing unit 400 measured by the second temperature sensor 520 may be transmitted to the calculating unit 600, and later calculating the radiation energy of the black body implementing unit 400 by the calculating unit 600. Can be utilized. This is described in detail below.

As described above, the values measured by the net radiation measuring unit 200 and the temperature measuring unit 500 may be transmitted to the calculating unit 600.

The calculating unit 600 may calculate the thermal characteristics of the greenhouse material S based on the values measured by the net radiation measuring unit 200 and the temperature measuring unit 500.

In this case, the thermal characteristics of the greenhouse material S may include reflectance, transmittance, or emissivity (or absorption) of the greenhouse material S.

Specifically, in the calculation unit 600, the puncture radiation energy is calculated from the upper temperature of the greenhouse material S measured by the first temperature sensor 510, and the black body realization unit 400 measured by the second temperature sensor 520. Radiation energy of the blackbody implementing unit 400 may be calculated from the temperature of.

In addition, the calculation unit 600, the difference in the net radiation amount in the upper and lower portions of the greenhouse material (S) measured by the net radiation measurement unit 200, for example, the net radiation amount measured by the first net radiation sensor 210 and the first Radiation energy of the greenhouse material S may be calculated from the difference in the net radiation amount measured by the 2 net radiation amount sensor 220.

Furthermore, in the calculation unit 600, the relationship between the puncture radiant energy, the radiant energy of the black body realization unit 400 and the radiant energy of the greenhouse material S and the upward radiant energy above the greenhouse material S, and the puncture The thermal characteristics of the greenhouse material (S) from the relationship between the radiant energy, the radiant energy of the black body realization unit 400 and the radiant energy of the greenhouse material (S) and the downward radiant energy from the upper portion of the greenhouse material (S) The reflectance and transmittance of the utility material S can be calculated.

For example, the calculation unit 600 has a first relational expression for perforated radiant energy, radiant energy of the blackbody implementing unit 400, radiant energy of the greenhouse material S, and upward radiant energy above the greenhouse material S. , Perforated radiant energy, radiation energy of the blackbody realization unit 400, the second relationship to the radiant energy of the greenhouse material (S) and the downward radiant energy under the greenhouse material (S), perforated radiant energy, blackbody implementation A third relational equation for the radiation energy of 400, the radiant energy of the greenhouse material S, and the upward radiant energy under the greenhouse material S may be embedded, and the first and second relational equations may be included in the greenhouse equation. The reflectance and transmittance of the material S may be included as the proportional constant, and the third relational expression may include the transmittance of the greenhouse material S as the proportional constant.

In addition, the calculation unit 600 may further include a fourth relational expression for reflectance, transmittance, and emissivity of the greenhouse material S, and the emissivity of the greenhouse material S may be calculated from the fourth relational expression.

As described above, at least one of the reflectance, transmittance, and emissivity of the greenhouse material S, which is a thermal characteristic of the greenhouse material S, may be calculated from various relational expressions built into the calculator 600.

Hereinafter, the process of calculating the thermal characteristics of the greenhouse material S in the calculation unit 600 will be described in more detail.

First, the calculator 600 may calculate the puncture radiant energy by the following equations.

At this time,

R ₁ is the puncture radiant energy,

σ is the Stefan Boltzmann constant,

T _S is the puncture temperature,

T _a is the temperature measured by the first temperature sensor 510.

Specifically, the temperature measured by the first temperature sensor 510 is transferred to the operation unit 600 to calculate the puncture temperature, and then the puncture radiant energy may be calculated based on the calculated puncture temperature.

In addition, the calculation unit may further calculate the radiation energy of the black body implementation unit 400 by the following equations.

At this time,

E _w is the radiation energy of the blackbody implementing unit 400,

ε _w is the emissivity of the blackbody implementing unit 400,

σ is the Stefan Boltzmann constant,

T _w is the temperature measured by the second temperature sensor 520,

ρ _w is a reflectance of the blackbody implementing unit 400.

In this case, the emissivity of the black body implementing unit 400 may be a separately measured value, and the reflectance of the black body implementing unit 400 may be calculated from the emissivity of the black body implementing unit 400.

Specifically, the temperature measured by the second temperature sensor 5200 may be transmitted to the calculator 600 to calculate the radiant energy of the blackbody implementer 400.

In addition, the operation unit 600 may further calculate the radiation energy of the greenhouse material S by the following equation.

At this time,

E _n is the radiant energy of the greenhouse material (S),

는 제1 순복사량 센서(210)에서 측정된 온실용 자재(S) 상부에서의 순복사량이고,

Is the net radiation amount from the upper greenhouse material (S) measured by the first net radiation sensor 210,

는 제2 순복사량 센서(220)에서 측정된 온실용 자재(S) 하부에서의 순복사량이고,

Is the net radiation amount under the greenhouse material S measured by the second net radiation sensor 220,

R ₁ is the puncture radiant energy,

R ₂ is the upward radiant energy at the top of the greenhouse material (S),

R ₃ is the downward radiant energy under the greenhouse material (S),

R ₄ is the upward radiant energy under the greenhouse material (S).

Specifically, the net radiation amount and the greenhouse material (S) at the lower portion of the greenhouse material (S) measured by the first net radiation sensor (210) and the second net radiation sensor (220), respectively, in the calculation unit 600 The net radiation amount is transmitted, and the radiation energy of the greenhouse material S may be calculated by the difference between the net radiation amount in the upper portion of the greenhouse material S and the net radiation amount in the lower portion of the greenhouse material S.

In addition, in the assembling unit 600, the reflectance, transmittance and emissivity of the greenhouse material S may be calculated by the following relational expressions.

The first relation is as follows.

At this time,

R ₂ is the upward radiant energy at the top of the greenhouse material (S),

R ₁ is the puncture radiant energy,

E _n is the radiant energy of the greenhouse material (S),

E _w is the radiation energy of the blackbody implementing unit 400,

ρ _n is the reflectance of the greenhouse material (S),

τ _n is the transmittance of the greenhouse material (S).

As described above, the first relational expression is a relational expression for the upward radiant energy, the perforated radiant energy, the radiant energy of the greenhouse material S, and the radiant energy of the black body realization unit 400, and the greenhouse material. The reflectance of (S) and the transmittance of the greenhouse material (S) may be included as proportional constants.

The second relation is as follows.

At this time,

R ₃ is the downward radiant energy under the greenhouse material (S),

R ₁ is the puncture radiant energy,

E _n is the radiant energy of the greenhouse material (S),

E _w is the radiation energy of the blackbody implementing unit 400,

ρ _n is the reflectance of the greenhouse material (S),

τ _n is the transmittance of the greenhouse material (S).

As described above, the second relational expression is a relational expression for the downward radiation energy under the greenhouse material S, the perforated radiation energy, the radiation energy of the greenhouse material S, and the radiation energy of the blackbody realization unit 400. The reflectance of (S) and the transmittance of the greenhouse material (S) may be included as proportional constants.

The third relation is as follows.

At this time,

R ₄ is the upward radiant energy under the greenhouse material (S),

R ₁ is the puncture radiant energy,

E _n is the radiant energy of the greenhouse material (S),

E _w is the radiation energy of the blackbody implementing unit 400,

ρ _w is the reflectance of the blackbody implementing unit 400,

τ _n is the transmittance of the greenhouse material (S).

As such, the third relation is a relational expression for upward radiant energy under the greenhouse material S, perforated radiant energy, radiant energy of the greenhouse material S, and radiant energy of the blackbody implementing unit 400. The transmittance of S and the reflectance of the blackbody implementing unit 400 may be included as proportional constants.

The fourth relation is as follows.

At this time,

ρ _n is the reflectance of the greenhouse material (S),

ε _n is the emissivity of the greenhouse material (S),

τ _n is the transmittance of the greenhouse material (S).

As such, the fourth relational expression is a relational expression for reflectance, transmittance and emissivity of the greenhouse material S.

및

에 대한 두 개의 수식이 정리될 수 있다.By using the first to third relations described above

And

Two equations for can be summarized.

에 대한 제1 수식이 정리될 수 있다. 이때, 제1 수식에서,

의 값은 제1 순복사량 센서(210)에서 측정된 온실용 자재(S) 상부에서의 순복사량이고, 천공 복사에너지, 흑체 구현부(400)의 방사에너지 및 온실용 자재(S)의 방사에너지는 연산부(600)에서 미리 산출될 수 있다. 따라서

에 대한 제1 수식에서 온실용 자재(S)의 반사율 및 온실용 자재(S)의 투과율이 미지수가 될 수 있다.Specifically, the calculation unit 600 by using the puncture radiant energy and the first relational expression

The first equation for can be summarized. At this time, in the first formula,

The value of is the net radiation amount in the upper portion of the greenhouse material (S) measured by the first net radiation sensor 210, the perforated radiant energy, the radiation energy of the black body realization unit 400 and the radiation energy of the greenhouse material (S) May be calculated in advance by the calculator 600. therefore

In the first equation for, the reflectance of the greenhouse material S and the transmittance of the greenhouse material S may be unknown.

에 대한 제2 수식이 정리될 수 있다. 이때, 제2 수식에서,

의 값은 제2 순복사량 센서(220)에서 측정된 온실용 자재(S) 하부에서의 순복사량이고, 천공 복사에너지, 흑체 구현부(400)의 방사에너지 및 온실용 자재(S)의 방사에너지는 연산부(600)에서 미리 산출될 수 있다. 그리고 흑체 구현부(400)의 반사율 또한 연산부(600)에서 미리 산출될 수 있다. 따라서

에 대한 제2 수식에서 온실용 자재(S)의 투과율만이 미지수가 될 수 있다.In addition, the calculation unit 600 may use the second relational expression and the third relational expression.

The second equation for can be summarized. At this time, in the second formula,

The value of is the net radiation amount under the greenhouse material (S) measured by the second net radiation sensor 220, the puncture radiation, the radiation energy of the black body realization unit 400 and the radiation energy of the greenhouse material (S) May be calculated in advance by the calculator 600. The reflectance of the black body implementing unit 400 may also be calculated in advance by the calculator 600. therefore

In the second equation for only the transmittance of the greenhouse material (S) can be unknown.

에 대한 제1 수식 및

에 대한 제2 수식을 연립하여 온실용 자재(S)의 열특성인 온실용 자재(S)의 반사율 및 온실용 자재(S)의 투과율이 산출될 수 있다. 그런 다음, 연산부(600)에서는 제4 관계식을 이용하여 온실용 자재(S)의 방사율이 산출될 수 있다.In this way, the calculation unit 600

First formula for and

By reflecting the second equation for, the reflectance of the greenhouse material S and the transmittance of the greenhouse material S which are thermal characteristics of the greenhouse material S may be calculated. Then, the calculation unit 600 may calculate the emissivity of the greenhouse material S using the fourth relational expression.

As described above, the thermal property measurement system 10 of a greenhouse material according to an embodiment may measure long-wave radiation characteristics (eg, reflectance, absorptivity, and transmittance) of a greenhouse material (insulating material, insulation, or light shielding material). In this regard, the thermal insulation performance of greenhouse materials can be quantitatively presented, and the long-wave radiation characteristics of greenhouse materials can be easily measured indoors or outdoors by installing a net radiation sensor on the upper and lower portions of the greenhouse materials. In addition, the thermal property measurement system 10 of the greenhouse material according to an embodiment measures the long-wave radiation characteristics of all the greenhouse materials spread in the country to analyze or compare the thermal insulation performance according to the type of greenhouse material In addition, since the greenhouse material is detachably attached to the frame, the long-wave radiation characteristics according to the combination of various greenhouse materials can be easily measured.

Although embodiments have been described by the limited drawings as described above, various modifications and variations are possible to those skilled in the art from the above description. For example, the described techniques may be performed in a different order than the described method, and / or components of the described structure, apparatus, etc. may be combined or combined in a different form than the described method, or may be combined with other components or equivalents. Appropriate results can be achieved even if they are replaced or substituted.

10: Measurement system for thermal properties of greenhouse materials
100: frame
200: net radiation measurement unit
210: first net radiation sensor
220: second net radiation sensor
300: fixed part
400: black body implementation
500: temperature measuring unit
510: first temperature sensor
520: second temperature sensor
600: calculation unit

Claims (11)

A frame configured to be mounted with greenhouse materials;
A black body implementing unit provided in the frame to implement a black body surface under the greenhouse material;
A net radiation measuring unit including a first net radiation sensor for measuring a net radiation amount at an upper portion of the greenhouse material and a second net radiation sensor for measuring a net radiation amount at a lower portion of the greenhouse material;
A temperature measuring unit including a first temperature sensor measuring an upper temperature of the greenhouse material and a second temperature sensor measuring a temperature of the blackbody implementing unit; And
A calculating unit calculating a thermal characteristic of the greenhouse material based on the values measured by the net radiation measuring unit and the temperature measuring unit;
Including,
Thermal properties of the greenhouse material includes the reflectance, transmittance or emissivity of the greenhouse material,
In the operation unit, the puncture temperature is calculated from the upper temperature of the greenhouse material measured by the first temperature sensor, and the puncture radiant energy is calculated based on the puncture temperature.
In the calculating unit, the radiant energy of the black body implementing unit is calculated from the temperature of the black body implementing unit measured by the second temperature sensor.
The calculation unit may be configured to determine the greenhouse material from the difference between the net radiation amount at the upper portion of the greenhouse material measured by the first net radiation amount sensor and the net radiation amount at the lower portion of the greenhouse material measured by the second net radiation amount sensor. Radiant energy is calculated,
The net radiation amount in the upper portion of the greenhouse material measured by the first net radiation amount sensor is a difference between the perforated radiation energy and the upward radiation energy in the upper portion of the greenhouse material, and the greenhouse use measured by the second net radiation amount sensor. The net radiation amount at the bottom of the material is the difference between the downward radiation at the bottom of the greenhouse material and the upward radiation at the bottom of the greenhouse material,
The calculation unit is a relational expression of the perforated radiant energy, the radiant energy of the blackbody realization unit and the radiant energy of the greenhouse material and the net radiant amount on the greenhouse material measured by the first net radiation sensor, and the perforated radiant energy, the The reflectance and transmittance of the greenhouse material are calculated from the relationship between the radiation energy of the blackbody realization unit and the radiation energy of the greenhouse material and the net radiation amount under the greenhouse material measured by the second net radiation sensor.
In the calculating unit, the emissivity of the greenhouse material is calculated from the relational expressions for the reflectance, transmittance and emissivity of the greenhouse material.
The method of claim 1,
In the calculation unit, the puncture radiant energy is calculated by the following equations,

At this time,
R ₁ is the puncture radiant energy,
σ is the Stefan Boltzmann constant,
T _S is the puncture temperature,
T _a is a thermal characteristic measurement system for a greenhouse material that is the temperature measured by the first temperature sensor.
The method of claim 2,
In the calculation unit, the radiation energy of the blackbody realization unit is further calculated by the following equations,

At this time,
E _w is the radiant energy of the blackbody implementation,
ε _w is the emissivity of the blackbody implementation,
T _w is the temperature measured by the second temperature sensor,
ρ _w is a thermal property measurement system of a greenhouse material that is the reflectance of the blackbody realization.
A frame configured to be mounted with greenhouse materials;
A black body implementing unit provided in the frame to implement a black body surface under the greenhouse material;
A net radiation measuring unit including a first net radiation sensor for measuring a net radiation amount at an upper portion of the greenhouse material and a second net radiation sensor for measuring a net radiation amount at a lower portion of the greenhouse material;
A temperature measuring unit including a first temperature sensor measuring an upper temperature of the greenhouse material and a second temperature sensor measuring a temperature of the blackbody implementing unit; And
A calculating unit calculating a thermal characteristic of the greenhouse material based on the values measured by the net radiation measuring unit and the temperature measuring unit;
Including,
Thermal properties of the greenhouse material includes the reflectance, transmittance or emissivity of the greenhouse material,
In the calculation unit, the puncture radiant energy is calculated by the following equations,

At this time,
R ₁ is the puncture radiant energy,
σ is the Stefan Boltzmann constant,
T _S is the puncture temperature,
T _a is the temperature measured by the first temperature sensor,
In the calculation unit, the radiation energy of the blackbody realization unit is further calculated by the following equations,

At this time,
E _w is the radiant energy of the blackbody implementation,
ε _w is the emissivity of the blackbody implementation,
T _w is the temperature measured by the second temperature sensor,
ρ _w is the reflectance of the blackbody implementation,
In the calculation unit, the radiation energy of the greenhouse material is further calculated by the following equation,

At this time,
E _n is the radiation energy of the greenhouse material,

Is the net radiation amount on top of the greenhouse material measured by the first net radiation amount sensor,

Is the net radiation amount under the greenhouse material measured by the second net radiation sensor,
R ₁ is the perforated radiant energy,
R ₂ is the upward radiant energy on top of the greenhouse material,
R ₃ is the downward radiant energy under the greenhouse material,
R ₄ is an upward radiant energy under the greenhouse material.
The method of claim 4, wherein
The calculation unit calculates the reflectance, transmittance and emissivity of the greenhouse material by the following relations,

At this time,
ρ _n is the reflectance of the greenhouse material,
ε _n is the emissivity of the greenhouse material,
τ _n is a thermal property measurement system of the greenhouse material which is the transmittance of the greenhouse material.
The method of claim 1,
Further comprising a fixing unit for holding the first net radiation sensor and the second net radiation sensor on the upper and lower parts of the greenhouse material,
The fixing portion is provided in the '''cross-sectional shape,
The first net radiation sensor is mounted on the upper end of the fixing portion,
The second net radiation sensor is mounted on the lower end of the fixing part,
The greenhouse material is disposed in the center of the side of the fixing portion, so that the distance between the first net radiation sensor and the second net radiation sensor from the greenhouse material is the same, the thermal characteristic measurement system of the greenhouse material.
The method of claim 1,
The greenhouse material includes a heat insulating material, a heat insulating material or a light shielding material, the thermal property measurement system of the greenhouse material.
The method of claim 1,
The blackbody realization unit is provided with a black cloth mounted on the frame, the thermal characteristic measurement system of the greenhouse material.
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