KR101304980B1 - U-value and g-value measuring apparatus - Google Patents

Abstract

PURPOSE: A U-value and G-value measurement device is provided to supply a stable current to a lamp and to obtain a lifetime extension and the stability of the lamp via individual control. CONSTITUTION: A U-value and G-value measurement device includes a solar light simulator (1000), an outdoor condition chamber (2100), and an indoor condition chamber (2200). The solar light simulator includes a body (1100) for providing a darkroom; a lamp emitting artificial solar light; a reflecting device (1300) transmitting the artificial solar light emitted by the lamp to the outside; and a lens collecting the artificial solar light transmitted from the reflecting device and transmitting the collected solar light to a desired position. The outdoor condition chamber includes a solar light introduction unit (2120); a frame (2150) for installing a target object; a current generation device (2130); and a fan heater (2140). The indoor condition chamber is joined to the outdoor condition chamber and includes an inner insulation wall (2250), an indoor temperature maintaining device (2230), a baffle plate (2240), and a heat quantity collecting device (2220).

Description

U-VALUE and G-VALUE Measuring Apparatus

The present invention relates to a u-value and a g-value measuring device, and more particularly, to a u-value and a g-value measuring device capable of simultaneously measuring the u-value and the g-value of a test body.

In general, products having heat insulating performance such as windows and windows determine the superiority of the product by measuring the U-values and G-values.

U-VALUE refers to the heat transmission rate or heat transmission rate in a dictionary meaning 'the amount of heat flowing when the unit time, unit area, and unit temperature difference of heat perfusion'. U-value is an important measure for insulation products such as windows and doors because it refers to the thermal insulation performance of windows and doors in which indoor heat is released to the outdoors or outdoor heat is introduced into the room.

In addition, G-VALUE has a dictionary meaning of 'a numerical value indicating the amount of chemical change in the radiation irradiation' and is commonly referred to as radiation shielding rate. Measuring the ground value of a product is to determine how far the product can block air radiation.

To measure u- and g-values, seasonal outdoor and solar environmental conditions are required. In the past, the u-value of the product was measured through a device using sunlight, and the g-value was measured in terms of shielding coefficient. However, the apparatus for measuring u-values using the conventional apparatus using sunlight does not satisfy the outdoor environmental conditions and does not control the artificial sunlight, and thus does not yield an effective u-value measurement value.

In addition, since the G-value was measured in terms of shielding coefficient, there was a wide range of error.

The present invention has been made to solve the above problems, an object of the present invention is to measure the paper-value of the test body to the experiment to calculate the amount of heat of sunlight entering the room through the test body.

Another object of the present invention is to measure the u-value of the test specimen by setting the indoor and outdoor environmental conditions according to the season.

Another object of the present invention is to measure the U-value and G-value by installing one test specimen.

In order to achieve the above object, the u-value and g-value measuring device of the present invention transmits a body for providing a dark room, a lamp that emits artificial sunlight, and artificial sunlight that emits light from the lamp to the outside. A solar simulator having a reflector, a lens for condensing the artificial sunlight transmitted from the reflector to a desired position, a first wall for partitioning the exterior and the interior, and one of the first walls. Photovoltaic inlet for introducing the artificial sunlight transmitted from the solar simulator to the side of the first wall, a frame formed to install a test body, and an airflow for controlling the airflow in the space inside the first wall An outdoor condition chamber having a generator, a fan heater for controlling the temperature of the interior space of the first wall, and an outdoor condition chamber A second wall for partitioning the inner wall, an inner insulation wall for reducing a temperature change generated through the second wall, an indoor temperature maintaining device for controlling an internal temperature of the inner insulation wall, and the test body It is provided with an indoor condition chamber having a bent plate to block the infrared radiation effect of the artificial sunlight transmitted to the virtual room through, and a calorie collection device for collecting the heat of the artificial sunlight transmitted through the bent plate.

The solar simulator includes a body for providing a dark room, a lamp for emitting artificial sunlight, a reflection shade reflecting the artificial sunlight of the lamp and collecting the artificial sunlight in one place, and the artificial sunlight reflected from the reflection shade. A first reflecting mirror reflecting at an angle of the first reflecting mirror, a second reflecting mirror formed at a predetermined angle to horizontally transmit the artificial sunlight transmitted from the first reflecting mirror, and transmitted from the second reflecting mirror A fly's eye lens for condensing the artificial sunlight, and the condenser lens for delivering the artificial sunlight collected in the fly's eye in a desired direction.

The chamber may further include a first wall for partitioning the exterior and the interior, and introducing the artificial sunlight transmitted from the solar simulator that generates artificial sunlight on one side of the first wall into the interior of the first wall. A solar inlet for providing a frame, a frame formed to install a test body on the first wall opposite to the solar inlet formed on the first wall, and an airflow generator for controlling the airflow in the interior space of the first wall; An outdoor condition chamber having a fan heater for controlling the temperature of the interior space of the first wall, a second wall coupled to the outdoor condition chamber, for partitioning the outdoor and the indoor, and a temperature generated through the second wall; An internal insulation wall for reducing the change, an indoor temperature maintaining device for controlling the internal temperature of the internal insulation wall, and a virtual room through the test body To block the infrared radiation that month artificial sun light impact bepul plate, may have an interior condition chamber having a heat collecting device for collecting the artificial sunlight heat transfer through the plate bepul.

According to the U-value and G-value measuring device according to the present invention, by providing one safety rectifier per lamp installed in the solar simulator of the U-value and G-value measuring device, stable current supply to the lamp and individual control It is possible to secure the life and stability of the lamp.

In addition, the test body can be conveniently installed by separating the outdoor condition chamber and the indoor condition chamber of the U-value and G-value measuring devices.

In addition, the air flow generator installed in the outdoor condition chamber of the U-value and G-value measuring devices can control the wind speed of the wind, so that the U-value and the G-value can be measured under the same environmental conditions as various outdoor air conditions.

1 is a cross-sectional view showing a U-value and G-value measuring apparatus according to an embodiment of the present invention.
2 is a cross-sectional view showing a solar simulator according to an embodiment of the present invention.
3 is a cross-sectional view showing a chamber according to an embodiment of the present invention.
4 is a cross-sectional view showing a state in which the chamber is separated according to an embodiment of the present invention.
5 is a cross-sectional view showing an outdoor condition chamber according to an embodiment of the present invention.
6 is a cross-sectional view showing an indoor condition chamber according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail for the U-value and G-value measuring apparatus according to an embodiment of the present invention.

1 is a cross-sectional view showing a U-value and G-value measuring apparatus according to an embodiment of the present invention.

As shown in FIG. 1, in the U-value and G-value measuring apparatus according to an embodiment of the present invention, an outdoor condition in which the solar simulator 1000 and the test body 2300 which emit artificial sunlight 3000 are installed. An indoor condition chamber 2200 for measuring the u-value and the g-value of the chamber 2100 and the test body 2300 is provided.

The solar simulator 1000 includes a box-shaped body 1100 to provide a dark room, and the lamp 1200 that emits artificial sunlight 3000 most similar to sunlight in the body 1100. And a reflector 1300 for reflecting the artificial sunlight 3000 emitted from the lamp 1200, and a lens 1400 for condensing the artificial sunlight 3000 transmitted from the reflector 1300 to a desired position. ).

A ventilation device 1610 and a filter 1620 are provided at the lower and upper portions of the body 1100 to allow air inside the body 1100 to circulate so that foreign matters such as dust from the outside penetrate into the body 1100. And removes heat from components inside the body 1100 by air circulation.

In addition, the reflector 1300 switches the reflection shade 1310 collecting the artificial sunlight 3000 emitted from the lamp 1200 and the direction of the artificial sunlight 3000 transmitted from the reflection shade 1310. A reflector 1320 is provided.

The constant lens 1400 may include a fly's eye lens 1410 that focuses the artificial sunlight 3000 and a condenser lens that delivers the artificial sunlight 3000 focused by the fly's eye lens 1410 in a desired direction. 1420.

In addition, a safety rectifier 1500 for stably supplying current to the lamp 1200 may include one safety rectifier 1500 per lamp 1200 to individually control the lamp 1200.

A ventilation device 1610 and a filter 1620 are provided at the lower and upper portions of the body 1100 to allow air inside the body 1100 to circulate so that foreign matters such as dust from the outside penetrate into the body 1100. And removes heat from components inside the body 1100 by air circulation.

In addition, the solar simulator 1000 is provided with a mobile device 5000 that enables movement.

The outdoor condition chamber 2100 may include a first wall 2110 for dividing the outdoor and the indoor space, and the artificial sunlight 3000 transmitted from the solar simulator 1000 to one side of the first wall 2110. ) Is introduced into the interior of the first wall 2110, the solar inlet 2120, the frame 2150 formed to install the test body 2300, and the air flow in the interior space of the first wall 2110 An airflow generating device 2130 for controlling and a fan heater 2140 for controlling the temperature of the inner space of the first wall 2110 are provided.

The airflow generator 2130 is provided at the lower end of the airflow generator 2130 to allow the airflow generator 2130 to be movable inside the outdoor condition chamber 2100.

In addition, a lower end of the outdoor condition chamber 2100 is provided with a mobile device 5000 to move the outdoor condition chamber 2100.

In addition, the outer wall of the first wall 2110 is provided with an air circulation device 2160 capable of circulating air.

The indoor condition chamber 2200 is coupled to the outdoor condition chamber 2100, and reduces a temperature change generated by passing through the second wall 2210 and the second wall 2210 for partitioning the outdoor and the indoor. Insulation wall 2250 for controlling, an indoor temperature maintaining device 2230 for controlling the internal temperature of the inner insulation wall 2250, and artificial sunlight transmitted to the virtual room through the test body 2300 ( And a heat collecting device 2220 for collecting heat of artificial sunlight 3000 transmitted through the beep plate 2240, and a bent plate 2240 for blocking the infrared radiation effect of the 3000.

A lower portion of the giving plate 2240 is provided with a DC fan 2260 and a DC heater 2270 for controlling the temperature of the indoor condition chamber 2200.

A rail 4000 is provided to provide a guideline to which each moving device 5000 moves so that the solar simulator 1000 and the outdoor condition chamber 2100 can move on the same line.

2 is a cross-sectional view showing a solar simulator according to an embodiment of the present invention.

As shown in FIG. 2, the solar simulator 1000 according to an embodiment of the present invention includes a lamp 1200 and a lamp 1200 that emit a body 1100 and artificial sunlight 3000 to provide a dark room. A reflector 1310 reflecting the artificial sunlight 3000, a reflector 1320 for changing the direction of the artificial sunlight 3000, and a fly-eye lens 1410 and an artificial sunlight condensing the artificial sunlight 3000. And a condenser lens 1420 for transferring the 3000 in a desired direction.

A safety rectifier 1500 for supplying a stable current to the lamp 1200 is further provided.

The ventilation device 1610 and the filter 1620 are provided in the upper portion of the body 1100 to prevent foreign matter from penetrating into the interior of the body 1100, and the ventilation device 1610 and the filter 1620 in the lower portion. It is provided to prevent foreign matter from penetrating into the body 1100 inside the body 1100, the air is circulated by the upper and lower ventilation device 1610 to remove the heat generated inside the body 1100. .

The lamp 1200 may use a xenon lamp that emits artificial sunlight 3000 that is most similar to sunlight, and xenon lamps may be installed with four or more 7KW, irradiating an area of 1,900mm X 1,600mm, and exposing the light. The distance is up to 5900mm. In addition, the lamp 1200 may emit a heat of 1,000 W / m 2 or more. In addition, the deviation of the light source distribution should be within ± 5.0%. In addition, the glass of the lamp 1200 may be heat-resistant temperature of 500 ℃, the quartz of the lamp 1200 can be applied to the temperature of the heat resistance temperature of 1100 ℃.

The safety rectifier 1500 individually controls one lamp 1200 per safety rectifier 1500 for stable driving of the lamp 1200, and provides a current up to 300A so that the lamp 1200 can adjust brightness. I can adjust it. In addition, although not shown in the figure, the stable rectifier is equipped with an ignition device applied up to 200A to supply a stable current to the lamp 1200 ignition, so that the life of the lamp 1200 can be extended.

The reflection shade 1310 is to collect the artificial sunlight 3000 emitted from the lamp 1200 by installing a reflector 1320 therein, is formed in the shape of a semi-ellipse, such as filament of the lamp 1200 It is installed at the lower end of the light emitting unit and collects the artificial sunlight 3000 emitted from the lamp 1200 as much as possible and reflects it.

The reflecting mirror has a first reflecting mirror and a second reflecting mirror. The first reflector 1321 may be installed at a predetermined angle to reflect the artificial solar light 3000 collected from the reflection shade 1310 and reflected upward. The second reflector 1322 is installed at a predetermined angle to horizontally reflect the artificial solar light 3000 reflected by the first reflector 1321.

The fly's eye lens 1410 collects artificial sunlight 3000 that is widely reflected by the second reflector 1322.

The condenser lens 1420 may transmit the artificial solar light 3000 collected by the fly's eye lens 1410 in a desired direction by adjusting an installation angle of the condenser lens 1420.

The fly's eye lens 1410 and the condenser lens 1420 are installed at one side of the body 1100 at a predetermined interval so that artificial sunlight 3000 emitted from the lamp 1200 can be delivered in a desired direction. To be able.

3 is a cross-sectional view illustrating a chamber according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view illustrating a state in which a chamber is separated according to an embodiment of the present invention.

As shown in FIGS. 3 to 4, the chamber 2000 according to an exemplary embodiment of the present invention is configured to provide U-value and G-value of the outdoor condition chamber 2100 and the test body 2300 on which the test body 2300 is installed. An indoor condition chamber 2200 to measure is provided.

The outdoor condition chamber 2100 includes a first wall 2110 for dividing the outdoor and the indoor, and introduces artificial sunlight 3000 into the first wall 2110 on one side of the first wall 2110. A frame 2150 formed to install the test body 2300 on the solar inlet 2120 and the first wall 2110 opposite to the solar inlet 2120 formed in the first wall 2110; An airflow generator 2130 for controlling the airflow in the interior space of the first wall 2110 and a fan heater 2140 for controlling the temperature of the interior space of the first wall 2110 are provided.

The first wall 2110 may use a urethane panel, and high emissivity paint may be used on the inner wall. In addition, the outer wall of the first wall 2110 is provided with an air circulation device 2160 capable of circulating air.

It is formed on one side of the first wall 2110, the solar inlet 2120 for introducing the artificial sunlight 3000 into the interior of the first wall 2110 is a high transmittance glass to block the effects of infrared radiation. .

On the side of the first wall 2110 opposite to the solar inlet 2120 formed on the first wall 2110, a frame 2150 for installing the test body 2300 is installed.

Inside the first wall 2110, an air flow generator 2130 and a fan heater 2140 for controlling the air flow in the space inside the first wall 2110 are installed, and the test body 2300 is installed and tested outdoors. To form a condition.

In addition, a movement device 5000 is provided at the lower end of the airflow generator 2130 to allow the airflow generator 2130 to move inside the outdoor condition chamber 2100.

In addition, the mobile device 5000 is also provided at the bottom of the outdoor condition chamber 2100 to move the outdoor condition chamber 2100.

The indoor condition chamber 2200 may include a second wall 2210 for dividing the outdoor and the indoor, an internal insulation wall 2250 inside the second wall 2210, and an internal temperature of the internal insulation wall 2250. An indoor temperature maintaining device 2230 for controlling, a bent plate 2240 for blocking the infrared radiation effect of the artificial sunlight 3000, and a heat collector 2220 for collecting the heat of the artificial sunlight 3000 Equipped.

The second wall 2210 uses a urethane panel 100T to prevent the amount of heat generated in the indoor condition chamber 2200 from being released to the outside.

An inner insulation wall 2250 is provided inside the second wall 2210 to maintain an internal temperature of the indoor condition chamber 2200, and black high emissivity paint is used on an inner wall of the inner insulation wall 2250.

An interior temperature maintaining device 2230 for controlling the internal temperature of the indoor condition chamber 2200 is provided inside the internal insulation wall 2250.

The plate 2240 is formed of a high transmission glass (low iron glass) to transmit the artificial sunlight 3000 transmitted through the test body 2300 and to block the infrared radiation effect.

In addition, the lower plate 2240 is provided with a DC fan 2260 for adjusting the heat transfer rate, the wind speed for controlling the temperature and the DC heater 2270 for controlling the temperature around the bevel plate 2240. The DC fan 2260 and the DC heater 2270 supply power by measuring voltage and current.

The calorie collection device 2220 is fixed to the inner insulation wall 2250 and measures the amount of heat flow of the artificial solar light 3000 passing through the test body 2300 and the bent plate 2240.

A pad 2300 is provided at a portion where the outdoor condition chamber 2100 and the indoor condition chamber 2200 are coupled to each other so that the indoor temperature of the indoor condition chamber 2200 does not change. The pads 2300 are respectively provided in the outdoor condition chamber 2100 and the indoor condition chamber 2200 to provide a double insulation effect.

For example, since the indoor condition chamber 2200 measures the U-value and the G-value of the test body 2300 installed in the outdoor condition chamber 2100, the part contacting the test body 2300 is open. Therefore, the temperature of the indoor condition chamber 2200 may vary due to a gap generated when the outdoor condition chamber 2100 and the indoor condition chamber 2200 are coupled to each other. Since the test condition is changed when the temperature of the indoor condition chamber 2200 is changed, an accurate measurement value cannot be obtained. Therefore, the pad 2300 is installed in a double portion at the portion where the indoor condition chamber 2200 and the outdoor condition chamber 2100 are combined. In order to prevent the temperature inside the indoor condition chamber 2200 from changing.

5 is a cross-sectional view illustrating an outdoor condition chamber according to an embodiment of the present invention.

As shown in FIG. 5, the outdoor condition chamber 2100 according to an embodiment of the present invention includes a first wall 2110 for dividing an outdoor and an indoor space, and artificial sunlight on one side of the first wall 2110. A test body (2120) for introducing the 3000 into the interior of the first wall (2110) and the first wall (2110) opposite the photovoltaic (2120) formed in the first wall (2110). The frame 2150 formed to install the 2300, the airflow generator 2130 for controlling the airflow in the interior space of the first wall 2110, and the fan heater 2140 for controlling the temperature of the interior space of the first wall 2110. ).

The first wall 2110 may use a urethane panel 100T having a thermal resistance of 4 m 2 K / W or more, and black high emissivity paint having an emissivity of 0.92 or more may be used for the inner wall. In addition, the outer wall of the first wall 2110 is provided with an air circulation device 2160 capable of circulating air.

It is formed on one side of the first wall 2110, the solar inlet 2120 for introducing the artificial solar 3000 into the interior of the first wall (2110) is a high transmittance glass is a heat resistance of 200 ℃ or more can be used And, it blocks the effects of infrared radiation of artificial sunlight (3000).

On the side of the first wall 2110 opposite to the solar inlet 2120 formed on the first wall 2110, a frame 2150 for installing the test body 2300 is installed. The frame 2150 may be made of plywood or iron plate, and the test body 2300 is provided with a material in which the specimen 2300 is not deformed, detached or damaged.

Inside the first wall 2110, an air flow generator 2130 and a fan heater 2140 for controlling the air flow in the space inside the first wall 2110 are installed, and the test body 2300 is installed and tested outdoors. Conditions can be formed. In order to test the test body 2300 as actually used in the outside air, a fan heater 2140 is installed to set an outdoor heat transfer rate to increase the temperature inside the first wall 2110, and airflow inside the first wall 2110. The generator 2130 is installed to control the wind speed of the outside air to adjust the condition of the coefficient of the surface heat transfer resistance to make the same wind speed as the outdoor side. The airflow generating device 2130 may adjust the wind speed by using an inverter capable of adjusting the wind speed. In addition, the airflow generating device 2130 is made of high transmittance glass (low iron glass) to transmit the artificial sunlight 3000.

For example, in order to create a summer outdoor condition, the fan heater 2140 is operated to raise the temperature in the outdoor condition chamber 2100 and the airflow generator 2130 is operated to determine the average wind speed in the area where the test body 2300 is installed. To maintain.

The airflow generator 2130 is provided at the lower end of the airflow generator 2130 to allow the airflow generator 2130 to be movable inside the outdoor condition chamber 2100.

In addition, the mobile device 5000 is provided at the lower end of the outdoor condition chamber 2100 so that the outdoor condition chamber 2100 can be separated from the indoor condition chamber 2200 to fix the test body 2300 to the frame 2150. have.

6 is a cross-sectional view showing an indoor condition chamber according to an embodiment of the present invention.

As shown in FIG. 6, the indoor condition chamber 2200 according to an embodiment of the present invention is coupled to the outdoor condition chamber 2100, and has a second wall 2210 for partitioning the outdoor and the indoor, and the second. An internal insulation wall 2250 for reducing a temperature change generated by passing through the wall 2210, an indoor temperature maintaining device 2230 for controlling an internal temperature of the internal insulation wall 2250, and the test body ( Collecting the heat amount of the artificial sunlight 3000 transmitted through the bevel plate 2240 and the bevel plate 2240 to block the infrared radiation effect of the artificial solar light 3000 transmitted to the virtual room through the 2300. A calorie collection device 2220 is provided.

The second wall 2210 may use a urethane panel 100T having a heat resistance of 4 m 2 K / W or more.

An inner insulation wall 2250 is provided inside the second wall 2210 to maintain an internal temperature of the indoor condition chamber 2200, and black high emissivity paint having an emissivity of 0.92 or more is provided on an inner wall of the inner insulation wall 2250. use.

An interior temperature maintaining device 2230 for controlling the internal temperature of the indoor condition chamber 2200 is provided inside the internal insulation wall 2250. The room temperature maintaining apparatus 2230 maintains 15-20 ° C. (± 0.5 ° C.).

The bevel plate 2240 transmits the artificial solar light 3000 that has passed through the test body 2300, and does not transmit infrared radiation of 3 μm or more, and blocks the infrared radiation effect to the bevel plate 2240 without transmitting it. It is formed of (low iron glass). Since the bent plate 2240 has a higher transmittance and a constant spectral characteristic than a general float plate glass, it hardly changes the spectral characteristics of the artificial solar light 3000.

In addition, the lower plate 2240 is provided with a DC fan 2260 and a DC heater 2270 for adjusting the heat transfer rate and controlling the temperature. The DC fan 2260 maintains the wind speed by installing a plurality of axial flow fans to change the voltage of the power supply to adjust the wind speed. The DC heater 2270 performs temperature control through power current control using a platinum resistance thermometer. The DC fan 2260 and the DC heater 2270 supply power by measuring voltage and current.

The heat collecting device 2220 is fixed to the internal insulation wall 2250, and although not shown in the drawing, a heat flow sensor for measuring a heat flow amount of the artificial solar light 3000 passing through the test body 2300 and the bent plate 2240. And a cold plate for removing the heat of the heat flow sensor that the temperature is increased by the heat of the artificial sunlight 3000 is provided.

Then, the test body 2300 is installed once by the heat flow sensor of the calorie collection device 2220, and measures both u-value and g-value.

When the u-value and the g-value measuring device of the present invention measures the u-value of the test body 2300, the u-value is measured by setting environmental conditions of the outdoor condition chamber 2100 and the indoor condition chamber 2200. When measuring the paper value of the test body 2300, the artificial light 3000 is emitted using the solar simulator 1000 to measure the paper value passing through the test body 2300.

U-value is a measure for determining whether the windows pass through the heat well, and thus it is not a measure of the amount of heat generated by the artificial solar light 3000. The outdoor environment conditions are formed using the 2130 and the fan heater 2140, and the indoor environment conditions are formed using the indoor temperature maintaining apparatus 2230 under the indoor conditions. -Measure the value.

For example, an outdoor environmental condition of the outdoor condition chamber 2100 is set to 30 ° C., and an indoor environmental condition is set to 20 ° C. to measure the u-value of the test body 2300 as time passes.

G-value is to determine how much the test object 2300 can block the radiation. When the artificial light 3000 is emitted from the lamp 1200 of the solar simulator 1000, the reflector 1320 and the lens 1400 The artificial sunlight 3000 is transmitted to the solar light introduction unit 2120 of the outdoor condition chamber 2100 through the light source. The photovoltaic introduction unit 2120 primarily transmits the artificial solar light 3000 to the test body 2300 by blocking the infrared radiation effect of the artificial light 3000 first, and transmits the artificial light 3000 to the test body 2300 and reduces the radiation while the radiation is reduced. (3000) penetrates the bent plate (2240) to block the infrared radiation effect secondly to measure the paper-value of the test body (2300) in the calorie collection device (2220).

In the above description of the U-value and G-value measuring apparatus according to an embodiment of the present invention, the spirit of the present invention is not limited to the embodiments presented herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

1000: solar simulator 1100: body
1200: lamp 1300: reflector
1310: reflector 1320: reflector
1400: lens 1500: safety rectifier
2000: chamber 2100: outdoor condition chamber
2110: first wall 2120: solar inlet
2130: air flow generator 2140: fan heater
2150: frame 2160: air circulation
2200: indoor condition chamber 2210: second wall
2220: heat collection device 2230: room temperature maintenance device
2240: giving plate 2250: internal insulation wall
2260: DC fan 2270: DC heater

Claims (16)

A body for providing a dark room, a lamp for emitting artificial sunlight, a reflector for transmitting the artificial sunlight emitted from the lamp to the outside, and condensing the artificial sunlight transmitted from the reflector to a desired position Solar simulator having a lens for transmitting,
A first wall for partitioning the exterior and the interior, a solar light introduction portion for introducing the artificial solar light transmitted from the solar simulator into the first wall on one side of the first wall, and a test body An outdoor condition chamber having a frame formed so as to be provided, an air flow generation device for controlling the air flow in the first wall interior space, and a fan heater for controlling the temperature of the first wall interior space;
In combination with the outdoor condition chamber, the second wall for partitioning the outdoor and indoor, the internal insulation wall for reducing the temperature change generated by passing through the second wall, and controls the internal temperature of the internal insulation wall It is provided with a device for maintaining a room temperature, a beeping plate for blocking the infrared radiation effect of the artificial sunlight transmitted to the virtual room through the test body, and a heat collection device for collecting the heat of the artificial sunlight transmitted through the bent plate U-value and G-value measuring device comprising an indoor condition chamber.
The method of claim 1,
The reflector includes a reflector for collecting the artificial sunlight emitted from the lamp,
U-value and G-value measuring device characterized in that it comprises a reflector for changing the direction of the artificial sunlight transmitted from the reflection shade.
The method of claim 1,
The lens is a fly-eye lens for condensing the artificial sunlight,
U-value and G-value measuring device, characterized in that it comprises a condenser lens for transmitting the artificial sunlight collected in the fly-eye lens in a desired direction.
The method of claim 1,
The u-value and paper-value measuring device is characterized in that the coating of high emissivity paint to reduce the measurement error due to the radiant heat inside the outdoor condition chamber and the indoor condition chamber.
The method of claim 1,
U-value and G-value measurement device, characterized in that the lower end of the solar simulator and the outdoor condition chamber is provided with a wheel to enable movement.
6. The method of claim 5,
U-value and G-value measuring device, characterized in that the rail between the solar simulator and the outdoor condition chamber has a wheel moving.
delete delete delete delete delete First wall for partitioning the outdoor and indoor, and a solar light introduction portion for introducing the artificial sunlight transmitted from the solar simulator for generating artificial sunlight on one side of the first wall into the interior of the first wall And a frame formed to install a test body on the first wall opposite the solar inlet formed on the first wall, an airflow generator for controlling the air flow in the first wall internal space, and inside the first wall. An outdoor condition chamber having a fan heater for controlling the temperature of the space,
In combination with the outdoor condition chamber, the second wall for partitioning the outdoor and indoor, the internal insulation wall for reducing the temperature change generated by passing through the second wall, and controls the internal temperature of the internal insulation wall It is provided with a device for maintaining a room temperature, a beeping plate for blocking the infrared radiation effect of the artificial sunlight transmitted to the virtual room through the test body, and a heat collection device for collecting the heat of the artificial sunlight transmitted through the bent plate U-value and G-value measuring device comprising an indoor condition chamber.
13. The method of claim 12,
The u-value and paper-value measuring device is characterized in that the coating of high emissivity paint to reduce the measurement error due to the radiant heat inside the outdoor condition chamber and the indoor condition chamber.
13. The method of claim 12,
U-value and G-value measuring device, characterized in that the pad is provided in a portion where the outdoor condition chamber and the indoor condition chamber is coupled.
13. The method of claim 12,
U-value and G-value measuring device further comprises a DC fan and a DC heater for adjusting the heat transfer rate, the temperature control the lower portion of the bent plate.
13. The method of claim 12,
U-value and G-value measuring device, characterized in that the lower end of the outdoor condition chamber is provided with a wheel to move the outdoor condition chamber.

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