KR101072824B1 - Calorie meter for measuring solar heat gain coefficient of window - Google Patents

Abstract

The present invention is a window of the window that can measure the heat performance and solar heat gain coefficient (Solar Heat Gain Coefficient) of the window or building envelope by measuring the heat flowing through the building envelope or window by natural light in the general external environment It relates to a calorimeter for measuring the four-row acquisition coefficient, the measurement object fixing member for installing the measurement object is installed in the opening of one side, the outer chamber having a space therein; An inner chamber installed in the outer chamber so as to be linearly displaceable with respect to the object to be measured and having a space therein in contact with a wall of the object to be measured; A heat absorbing plate installed in the inner chamber and absorbing a part of the inlet radiation heat incident through the object to be measured; An internal heat exchanger disposed in the inner chamber behind the heat absorbing plate with respect to the object to be measured and absorbing the remainder of the incoming heat radiation incident through the object to be measured; An external heat exchanger installed in a space between the outer chamber and the inner chamber and maintaining a constant temperature in the outer chamber; An internal air thermometer and an external air thermometer installed in the inner chamber and the outer chamber; A heat source system for supplying a heat medium to the internal heat exchanger and the external heat exchanger and the heat absorption plate; A second heat medium thermometer and a third heat medium thermometer installed to measure the inlet / outlet temperature of the internal heat exchanger; A first thermal medium thermometer and a fourth thermal medium thermometer installed to measure an entry / exit side temperature of the heat absorption plate; A first heat medium flow meter and a second heat medium flow meter for measuring the flow rates of the heat medium flowing through the heat absorption plate and the internal heat exchanger, respectively; And a linear displacement driving unit for linearly displacing the inner chamber with respect to the object to be measured fixed member with respect to the outer chamber.

Calorimeter, solar radiation, window

Description

Calorimeter for measuring solar heat gain coefficient of windows and doors {Calorie meter for measuring solar heat gain coefficient of window}

The present invention relates to a calorimeter for measuring the solar heat gain coefficient of windows and doors, and more particularly, the thermal performance and solar heat of windows or building skins by measuring heat introduced through the building skin or windows by natural light in a general external environment. The present invention relates to a calorimeter for measuring the solar heat gain coefficient of windows and doors capable of measuring and calculating a solar heat gain coefficient.

Recently, the area of a window or a transparent building envelope is expanded in a building, and thus energy saving and comfort of the window or building envelope is required. Therefore, it is important to evaluate whether or not the window or the building envelope exhibits performance such as solar shielding performance.

However, such a window or building envelope functions together with the air conditioning and ventilation system of the building, and it is difficult to evaluate actual performance only with materials such as glass.

An object of the present invention devised to solve the above problems is to measure and calculate the thermal performance and solar heat gain coefficient of windows or buildings by measuring heat flowing through the building envelope or windows by natural light in a general external environment. The present invention provides a calorimeter for measuring the thermal gain coefficient of windows and doors.

The present invention for achieving the above object, the measurement object fixing member for installing the object to be installed in the opening on one side, the outer chamber having a space therein; An inner chamber installed in the outer chamber so as to be linearly displaceable with respect to the object to be measured and having a space therein in contact with a wall of the object to be measured; A heat absorbing plate installed in the inner chamber and absorbing a part of the inlet radiation heat incident through the object to be measured; An internal heat exchanger disposed in the inner chamber behind the heat absorbing plate with respect to the object to be measured and absorbing the remainder of the incoming heat radiation incident through the object to be measured; An external heat exchanger installed in a space between the outer chamber and the inner chamber and maintaining a constant temperature in the outer chamber; An internal air thermometer and an external air thermometer installed in the inner chamber and the outer chamber; A heat source system for supplying a heat medium to the internal heat exchanger and the external heat exchanger and the heat absorption plate; A second heat medium thermometer and a third heat medium thermometer installed to measure the inlet / outlet temperature of the internal heat exchanger; A first thermal medium thermometer and a fourth thermal medium thermometer installed to measure the temperature at the entry / exit side of the heat absorption plate; A first heat medium flow meter and a second heat medium flow meter for measuring the flow rates of the heat medium flowing through the heat absorption plate and the internal heat exchanger, respectively; And a linear displacement driving unit for linearly displacing the inner chamber with respect to the object to be measured fixed member with respect to the outer chamber.

An inner heat insulating member and an outer heat insulating member are installed on each of the wall surfaces of the inner chamber and the outer chamber.

In addition, the heat absorption plate is characterized in that the heat absorption plate is installed in the inner chamber by the heat absorption plate fixing member to block the heat conduction with the inner chamber.

In addition, the heat absorption plate fixing member is characterized in that the polyurethane.

In addition, the heat medium is characterized in that the water.

The linear displacement drive unit may include a guide provided in one of the inner chamber and the outer chamber, a slider movable through the guide, and an inner chamber driving means for linearly moving the slider with respect to the guide. It is characterized by.

In addition, the outer chamber is mounted to the solar tracking device, it is characterized in that it can track the altitude and azimuth of the sun.

Through the present invention, it is possible to measure and calculate the thermal performance and solar heat gain coefficient of windows or building envelopes in an environment equivalent to that of a real building by measuring heat flowing through the building envelope or windows by natural light in a general external environment. have.

Therefore, the measured values of the thermal performance and the solar heat gain coefficient at the test stage can be quite reliable, which can reduce trial and error in the development of windows or building envelopes.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

The calorimeter 100 for measuring the solar heat gain coefficient of a window according to an embodiment of the present invention includes an external chamber 102 that provides a constant measurement environment for the outdoors, and an internal chamber 110 installed in the external chamber 102. And an object to be measured 200 is installed in the opening of the outer chamber 102 and extends into the opening of the inner chamber 110 to between the object 200 and the inner chamber 110. And a measurement target fixing member 112 forming a measurement space.

The inner walls of the outer chamber 102 and the inner chamber 110 are provided with heat insulating members 104 and 116 for insulating the outside.

Preferably, the measurement space may have a predetermined size regardless of the thickness of the object 200. Accordingly, the measurement calorimeter 100 according to the embodiment of the present invention has a linear displacement in which the inner chamber 110 is displaced in a direction perpendicular to the plane of the object 200 with respect to the outer chamber 102. It has a driving part. Guides 106 and 178 are installed on the inner wall surface of the outer chamber 102, and sliders 108 and 180 moving along the guide 106 are installed on the outer wall surface of the inner chamber 110.

An inner chamber driving means 176 is connected to at least one of the guides 106 and 178, and a guide 106 connected to the inner chamber driving means 176 is formed of a rotatable feed screw. The burning slider 108 also has a female screw (not shown) that can screw onto the feed screw. Therefore, as the inner chamber driving means 176 rotates forward or reverse, the inner chamber 110 integral with the slider 108 is horizontally displaced with respect to the outer chamber 102.

Alternatively, the guides 106 and 178 and the sliders 108 and 180 may slide with each other, and a linear motor that pushes or pulls the inner chamber 110 may be used.

The measurement object fixing member 112 is in contact with the inner wall surface or the outer wall surface of the inner chamber 110, so that the air in the inner chamber 110 between the outer chamber 102 and the inner chamber 110; Do not mix air with each other.

In addition, the measurement object fixing member 112 extends in the direction of displacement of the inner chamber 110, so that despite the displacement of the inner chamber 110, the inner wall surface or the outer wall surface of the inner chamber 110 at all times. Keep in contact with.

In the inner chamber 110, a heat absorbing plate 114 for absorbing the inlet radiation heat passing through the object 200 is fixed to the inner chamber 110 by the heat absorbing plate fixing member 182. . The heat absorption plate fixing member 182 is to be made of a heat exchanger blocking material to block heat exchange of the inner chamber 110, polyurethane may be used as such a heat exchanger blocking material.

In addition, an internal heat exchanger 120 is installed in the inner chamber 110 so as to absorb the remaining amount of inlet radiation heat that is not absorbed by the heat absorption plate 114. The internal heat exchanger 118 is a heat exchanger in which a pipe through which refrigerant passes through is connected to the heat source system 122 installed outside the outer chamber 102, and a fan is mounted to facilitate heat exchange by convection.

In addition, an external heat exchanger 120 is installed in the outer chamber 102 to remove the influence of heat from the outside. The external heat exchanger 120 is a heat exchanger in which a pipe through which the refrigerant passes through is connected to the heat source system 122, and a fan is installed to facilitate heat exchange by convection.

Also. The heat absorption plate 114 is also connected to the heat source system 122, so that it is possible to discharge the incoming solar heat absorbed by conduction with the refrigerant.

Refrigerant used in the heat source system 122 may use water, and the first to the first for supplying water to the heat absorption plate 114, the internal heat exchanger 118, and the external heat cooler 120 Three pumps 124, 126 and 128 are installed.

In addition, the internal chamber 110 and the external chamber 102 are provided with an internal air thermometer 162 and an external air thermometer 160 for measuring room temperature so as to maintain a constant temperature.

In addition, in order to measure the amount of heat of the inlet radiation heat flowing into the inner chamber 110 by the measured object 200, the second refrigerant thermometer 166 and the second refrigerant thermometer 166 are respectively provided on the input side and the output side of the internal heat exchanger 118. A third refrigerant thermometer 168 is installed, and a first refrigerant thermometer 164 and a fourth refrigerant thermometer 170 are installed on the input side and the output side of the heat absorption plate 114, respectively. In addition, a first flowmeter 172 is installed on either the input side or the output side of the internal heat exchanger 118, and a second flowmeter 174 is installed on either the input side or the output side of the heat absorption plate 114. .

Therefore, the amount of heat of the inlet solar heat introduced by the measured object 200 is determined by the temperature difference between the inlet and outlet temperatures of the refrigerant circulating through the heat absorption plate 114 and the internal air heat exchanger 118 of the inner chamber 110. Calculate by adding the product.

Calorimeter 100 for measurement according to an embodiment of the present invention is basically configured as described above. Hereinafter, the mounting structure of the measurement calorimeter 100 will be described.

As shown in FIG. 3, the calorimeter 100 for measurement is mounted to the solar tracking device to change the azimuth angle and the altitude angle in order to maximize the insolation amount according to the altitude of the sun. The solar tracking device may use a known technique, and the solar tracking device used in the embodiment of the present invention is as follows.

The solar tracking device includes an anchor 132 installed on a foundation 130 such as the ground, a base 134 integrally fixed to the anchor 132, and a vertical direction with respect to the base 134 as a rotation axis. Rotary plate 136 rotatably installed, azimuth driving means for rotating the rotary plate 136, an installation bracket 142 fixedly fixed to the rotary plate 136, and one end of the installation bracket 142 And a fixed frame 156 fixed to the other end and rotatably fixed to the other end by the joint 158 and the mounting bracket 142 and fixed to the mounting calorimeter 100 of the measurement calorimeter 100. It is configured to include an altitude angle driving means for adjusting the altitude.

The azimuth driving means includes a first motor 138 fixed to the mounting bracket 142, and a rotation mechanism for transmitting the rotational driving force of the first motor 138 to the gear formed integrally with the rotating plate 136. do. Therefore, the azimuth angle of the calorimeter 100 for measurement can be adjusted by rotating the first motor 138.

In addition, the elevation angle driving means is a rail 146 fixed to the mounting bracket 142, the movable member 150 capable of horizontal movement by riding the rail 146, the lower side of the movable member 150 The screw feeder 148 is screwed with the formed saddle 149 and driven by a second motor 144 connected integrally, one end is fixed to the moving member 150 and the other end is the calorimeter 100 for measurement. Actuator 152 is fixed to the bottom of the. Therefore, the altitude angle of the calorimeter 100 for measurement can be adjusted by the movement of the second motor 144 and the actuator 152.

As described above, it has been described with reference to the preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

1 is a schematic cross-sectional view of a calorimeter for measuring the solar thermal gain coefficient of a window according to an embodiment of the present invention.

Figure 2 is a side cross-sectional view of the calorimeter for measuring the solar thermal gain coefficient of the window of Figure 1;

3 is a side view of a state in which the calorimeter for measuring the solar heat gain coefficient of the window of FIG. 1 is installed.

<Description of the symbols for the main parts of the drawings>

100: calorie meter 102: outer chamber

104: external insulation member 106, 178: guide

108,180: slider 110: inner chamber

112: measuring object fixing member 114: heat absorption plate

116: internal heat insulating member 118: internal heat exchanger

120: external heat exchanger 122: heat source system

124: first pump 126: second pump

128: third pump 130: foundation

132: anchor 134: base

136: rotating plate 138: the first motor

140: rotating mechanism 142: mounting bracket

144: second motor 146: rail

148: Moving Screw 149: Saddle

150: moving member 152: actuator

156: fixed frame 158: joint

160: outside air thermometer 162: inside air thermometer

164: first thermal medium thermometer 166: second thermal medium thermometer

168: third thermal medium thermometer 170: fourth thermal medium thermometer

172: first thermal medium flow meter 174: second thermal medium flow meter

176: inner chamber driving means 182: heat absorption plate fixing member

200: measured object

Claims (7)

An outer chamber having a measurement target fixing member for installing the measurement target in an opening of one side and having a space therein; An inner chamber installed in the outer chamber so as to be linearly displaceable with respect to the object to be measured and having a space therein in contact with a wall of the object to be measured; A heat absorbing plate installed in the inner chamber and absorbing a part of the inlet radiation heat incident through the object to be measured; An internal heat exchanger disposed in the inner chamber behind the heat absorbing plate with respect to the object to be measured and absorbing the remainder of the incoming heat radiation incident through the object to be measured; An external heat exchanger installed in a space between the outer chamber and the inner chamber and maintaining a constant temperature in the outer chamber; An internal air thermometer and an external air thermometer installed in the inner chamber and the outer chamber; A heat source system for supplying a heat medium to the internal heat exchanger and the external heat exchanger and the heat absorption plate; A second heat medium thermometer and a third heat medium thermometer installed to measure the inlet / outlet temperature of the internal heat exchanger; A first thermal medium thermometer and a fourth thermal medium thermometer installed to measure an entry / exit side temperature of the heat absorption plate; A first heat medium flow meter and a second heat medium flow meter for measuring the flow rates of the heat medium flowing through the heat absorption plate and the internal heat exchanger, respectively; And a linear displacement driving unit for linearly displacing the inner chamber with respect to the measurement target fixing member with respect to the outer chamber. The calorimeter of claim 1, wherein an inner heat insulating member and an outer heat insulating member are installed on each of the inner and outer walls of the inner chamber. The calorimeter of claim 1, wherein the heat absorption plate is installed in the inner chamber such that heat conduction with the inner chamber is blocked by a heat absorption plate fixing member. According to claim 3, wherein the heat absorption plate fixing member is a calorimeter for measuring the solar heat gain coefficient, characterized in that the polyurethane. The calorimeter of claim 1, wherein the heat medium is water. The linear displacement drive unit according to claim 1, wherein the linear displacement driving unit includes a guide provided in one of the inner chamber and the outer chamber, a slider movable through the guide, and an inner chamber drive for linearly moving the slider with respect to the guide. Calorimeter for insolation heat gain coefficient measurement, comprising a means. The calorimeter of claim 1, wherein the outer chamber is mounted to a solar tracking device to track the altitude and azimuth of the sun.

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