KR20150071148A - Method of measuring structural glass heat transmission coefficient - Google Patents

Abstract

A method for measuring the heat transmission coefficient of a glass for the construction is provided. The method comprises the steps of: preparing a heat source; installing a glass for construction and a thermocouple at an upper part of the heat source; raising the temperature of the glass for construction up to a normal temperature; calculating average temperature (Tglass) by measuring the temperature of a center part of the glass for construction when the temperature of the glass for construction reaches the normal temperature; measuring an atmospheric temperature (Troom) when the temperature of the glass for construction reaches a normal temperature; and calculating a heat transmission coefficient (Uglass) of the glass for construction.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a method for measuring a glass-

And to a method for measuring a glass thermal-conduction ratio.

The energy consumed in the building sector is about 25% of the total energy consumption in Korea, and the energy loss through the windows is about 35% of the total energy consumption of the building. This is due to the fact that the heat conduction rate of the window is about 2 to 5 times higher than that of the wall or roof, which is the weakest part of the exterior of the building envelope.

Recently, researches and developments have been actively carried out to develop a high thermal insulation window having a heat conduction ratio similar to that of a wall in terms of energy conservation in buildings as well as energy conservation in the whole country.

Furthermore, the insulation performance requirements for building envelopes, especially windows, are increasing due to the regulation of energy consumption and carbon dioxide emissions, so research on raw materials and manufacturing processes of the most excellent insulating glass in window glass, namely vacuum glass, ought.

One embodiment of the present invention provides a method for measuring a glass thermal efficiency of a building, which can measure an accurate thermal conduction rate using a heat source, glass for construction and a thermocouple.

In one embodiment of the present invention, there is provided a method comprising: providing a heat source; Installing a glass for construction and a thermocouple on the heat source; Raising the temperature of the building glass to a normal temperature; Calculating a mean temperature (Tglass) by measuring a temperature of the central portion of the building glass when the temperature of the building glass reaches a normal temperature; Measuring an ambient temperature (Troom) when the temperature of the building glass reaches a normal temperature; And calculating a heat transmission rate (Uglass) of the building glass.

The step of providing a heat source may include maintaining the temperature of the heat source at about 80 캜 to about 120 캜.

The heat source may have a size of width X length of about 150 mm X about 150 mm to about 200 mm X about 200 mm.

The architectural glass may include Roy glass, vacuum glass, multi-layer glass or triple glass.

The architectural glass may have dimensions of about 300 mm X about 500 mm to about 1200 mm X about 1200 mm in width X length.

The step of installing the building glass and the thermocouple on the heat source may include a step of placing the building glass center on the heat source.

The building glass core may include five RBs.

The five RBs may include one center point and four rim points spaced the same distance from the center point.

The distance between the center point and the fringe point may be about 10 mm to about 50 mm.

The normal temperature may be a temperature at which the temperature of the building glass and the temperature of the heat source are kept the same.

By using the above-mentioned method for measuring the glass thermal-permeability for building, it is possible to measure the heat-conduction rate in a simple and quick manner.

By using the above-mentioned method for measuring a glass thermal efficiency, it is possible to improve the accuracy of the value of the thermal efficiency of the glass for construction.

FIG. 1 is a graphical representation of the above-mentioned measurement method of the glass thermal-percussion ratio for construction.
FIG. 2 is a schematic representation of five RBs included in the central portion of the building glass.
FIG. 3 is a graph showing the values of Roy's glass heat-percussion ratio in Examples 1 to 4.

Hereinafter, embodiments of the present invention will be described in detail. However, the present invention is not limited thereto, and the present invention is only defined by the scope of the following claims.

In one embodiment of the present invention, there is provided a method comprising: providing a heat source; Installing a glass for construction and a thermocouple on the heat source; Raising the temperature of the building glass to a normal temperature; Calculating a mean temperature (Tglass) by measuring a temperature of the central portion of the building glass when the temperature of the building glass reaches a normal temperature; Measuring an ambient temperature (Troom) when the temperature of the building glass reaches a normal temperature; And calculating a heat transmission rate (Uglass) of the building glass.

Recently, it is required to increase the heat insulation performance of architectural glass for energy saving. At this time, the heat insulating performance of the glass for construction can be inferred by the heat conduction ratio, and the heat conduction ratio of the glass for construction is measured, calculated and analyzed. In most cases, the heat conduction ratio is measured by using the method of measuring the heat conduction rate of the window. However, the method of measuring the heat conduction rate of a window is very large, the size of the window is 1.5X1.5 m (width X length) or more, and the time required takes about 6 hours. In the case of architectural glass, The method of measuring the heat conduction rate of the window can be greatly different from the heat conduction rate of the architectural glass by measuring the value over the whole area.

Accordingly, one embodiment of the present invention can improve the accuracy of the value of the heat conduction rate of the glass for construction by providing a measurement method capable of measuring the heat conduction rate of the glass for construction in a simple and quick manner.

FIG. 1 is a graphical representation of the above-mentioned measurement method of the glass thermal-percussion ratio for construction. Referring to FIG. 1, a glass 20 for construction and a thermocouple can be installed on the heat source 10, and the thermocouple is used for measuring the atmospheric temperature.

For example, when the temperature of the heat source is maintained at about 100 ° C, the temperature of the building glass is raised to 100 ° C, and then the temperature of the central portion of the building glass is measured to calculate an average temperature (Tglass). In addition, it is possible to calculate the Uglass of the building glass by measuring the atmospheric temperature (Troom) when the temperature of the building glass is maintained at 100 캜. The atmospheric temperature (Troom) can be measured by a thermocouple installed on the heat source (10).

The heat transfer coefficient is a value expressing the heat insulating property against the total wall thickness for the multi-walled wall. It means the heat transmitted through the wall to the 1 ° C temperature difference between the inside and outside of the unit time and the unit area. Do. The above-mentioned method for measuring the glass thermal efficiency of the building can more accurately measure the thermal efficiency and minimize the error from the thermal efficiency of the actual building glass.

The step of providing the heat source may include maintaining the temperature of the heat source at about 80 ° C to about 120 ° C. The heat source is for heating the building glass, and a heat plate applied by conduction is suitable.

In addition, the heat source may have a size of width X length of about 150 mm X about 150 mm to about 200 mm X about 200 mm. For example, when the heat source is a hot plate, the error of the measured value of the heat conduction rate can be minimized by maintaining the size of the width X length in the above range.

For example, when the temperature of the heat source is 100 ° C and the width X vertical size of the heat source is 180mm X 180mm, the heat transmission rate (Uglass) of the building glass can be calculated by the following equation. Specifically, when the temperature of the heat source is maintained below about 80 ° C, the temperature range measured at the thermocouple is lower than the temperature range measured at 100 ° C, which can greatly affect the measurement error of the thermocouple. There is a fear of glass breakage.

[expression]

Uglass (占 폚) = 0.07874Tglass (占 폚) - 0.06307Troom (占 폚) - 0.046929

The architectural glass may include Roy glass, vacuum glass, multi-layer glass or triple glass. The low-temperature glass is referred to as a low-emissivity glass having a low emissivity. Royi glass can be used as double layer glass or triple layer glass, and it can realize effects such as energy saving, noise shielding and condensation reduction on glass surface due to high heat insulation performance. The double-layered glass has an air layer between the glass and the glass, while the vacuum glass has a vacuum between the glass and the glass, thereby reducing the amount of heat energy escaping the window and thus has an effect of preventing heat and condensation. Architectural glass may also contain triple glass to maximize thermal efficiency.

The architectural glass may have dimensions of about 300 mm X about 500 mm to about 1200 mm X about 1200 mm in width X length. For example, a construction glass having a size of about 600 mm × about 600 mm and about 1000 mm × about 1000 mm may be used for measuring the heat flow rate of the glass for the building. By using the construction glass within the above range, it is possible to measure the heat conduction rate of most glass size, which is advantageous in that one person can conveniently measure it.

The step of installing the building glass and the thermocouple on the heat source may include a step of placing the building glass center on the heat source. The central portion of the building glass may be a central portion of the building glass and may include five RBs for calculating an average temperature of the central portion of the building glass. FIG. 2 is a schematic representation of five RBs included in the central portion of the building glass.

The five RBs may include one center point T3 and four ridge points T1, T2, T4, and T5 spaced the same distance from the center point T3. The center point refers to a point where the horizontal and vertical vertices of the building glass are diagonally connected to each other and can be adjusted according to the size of the building glass. The marginal points may be vertices of the square when forming a square around the center point, and the distances between the marginal points and the center point are the same.

Specifically, the distance between the center point and the fringe point may be about 10 mm to about 50 mm. It is advantageous in that when the spacing distance is excellent in the above range, the error of the temperature measured away from the center of the heat source may become large.

The normal temperature may be a temperature at which the temperature of the building glass and the temperature of the heat source are kept the same. For example, the heat source may be maintained at about 80 ° C to about 120 ° C, and the normal temperature is in a range of about 80 ° C to about 120 ° C. For example, if the heat source is maintained at about 100 ° C, The temperature of the central portion of the building glass can be measured after the temperature of the building glass reaches about 100 캜 by the heat source.

Hereinafter, specific embodiments of the present invention will be described. However, the embodiments described below are only intended to illustrate or explain the present invention, and thus the present invention should not be limited thereto.

< Example >

Example  One

A hot plate of 180X180 mm (width X length) was maintained at 100 DEG C, and a Roy glass and a thermocouple were provided on the above heat plate. The temperature (Tglass) was calculated by measuring the temperature of one of the center point and the four outermost points of the Roy glass after the Roy glass (300 mm × 500 mm, width X length) reached 100 ° C. In addition, the air temperature (Troom) at the time when the temperature of the glass fell to 100 ° C was measured by the thermocouple, and the glass transition temperature (Uglass) of the glass was calculated by the following equation.

[expression]

Uglass (占 폚) = 0.07874Tglass (占 폚) - 0.06307Troom (占 폚) - 0.046929

Example  2

The heat conduction rate of the Roye glass was calculated in the same manner as in Example 1 except that the size of the Roye glass was changed to 600 X 600 mm (width X length).

Example  3

The heat conduction ratio of the red glass was calculated in the same manner as in Example 1, except that the size of the red glass was changed to 1000X1000 mm (width X length).

Example  4

The heat conduction rate of the Royer glass was calculated in the same manner as in Example 1 except that the size of the Royer glass was 1200 X 1200 mm (X lengthwise).

< Experimental Example > - Roy Glass Thermal  Measure

The values of the heat conduction rates were calculated according to the average temperature (Tglass) and the atmospheric temperature (Troom) of the Roy glass measured in Example 1, and the calculated values are shown in Table 1 below. Referring to Table 1, it can be seen that the error range between the value of the thermal conductivity and the actual value of the glass measured by the method of Example 1 is 0.1 or less. The value of the actual heat transmission rate of the Royer glass was measured according to the KS L2525 standard.

Temperature (℃) Thermal Permeability (Uglass, W / m ² K) Troom The average (Tglass) Actual value Example 1 GAP 14 28.1 0.8 0.86 -0.06 14.5 32.2 1.1 1.15 -0.05 14. 32.7 1.1 1.17 -0.07 914.5 39.3 1.75 1.71 0.04 19.6 34.6 1.1 1.02 0.08 22 34.2 0.9 0.84 0.06 22 44.9 1.75 1.68 0.07 23 45.2 1.75 1.64 0.10 23.7 54.1 2.3 2.30 0.00 24 38.8 1.1 1.07 0.03 27.1 38.7 0.9 0.87 0.03 27.3 38.7 0.9 0.86 0.04 27.6 57 2.3 2.28 0.03 28.1 57 2.3 2.25 0.05 32.1 42.6 0.9 0.86 0.04

Fig. 3 shows the values of the Royer glass heat-percussion ratio of Examples 1 to 4, wherein the heat-conduction rate of Example 1 was 0.884 W / m ² K, the heat-conduction rate of Example 2 was 0.907 W / m ² K, The heat conduction rate was 0.883 W / m ² K, and the heat conduction rate of Example 4 was 0.853 W / m ² K. All of the values of the heat conduction rates of Examples 1 to 4 were 0.9 W / m ² K, Respectively. At this time, it was found that the error was the smallest at 0.007 W / m ² K in the case of Example 2.

10: Heat source
20: Architectural glass
T3: Center point
T1, T2, T4, T5: Outermost point
T6: Ambient temperature
d: separation distance

Claims (10)

Providing a heat source;
Installing a glass for construction and a thermocouple on the heat source;
Raising the temperature of the building glass to a normal temperature;
Calculating a mean temperature (Tglass) by measuring a temperature of the central portion of the building glass when the temperature of the building glass reaches a normal temperature;
Measuring an ambient temperature (Troom) when the temperature of the building glass reaches a normal temperature; And
(Uglass) of the building glass
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
Wherein the step of providing a heat source comprises maintaining the temperature of the heat source at 80 ° C to 120 ° C
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
The heat source has a size of a width X length of 150 mm X 150 mm to 200 mm X 200 mm
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
The architectural glass may include Roy glass, vacuum glass, multi-layer glass or triple glass
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
The construction glass has a width X length of 300 mm X 500 mm to 1200 mm X 1200 mm
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
Wherein the step of installing the building glass and the thermocouple on the heat source includes the step of placing the building glass center on the heat source
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
Wherein the building glass center portion includes five RBs
A Method for Measuring the Thermal Permeability of Building Glass.
8. The method of claim 7,
The five RBs include four center points separated by the same distance from the center point
A Method for Measuring the Thermal Permeability of Building Glass.
9. The method of claim 8,
The distance between the center point and the fringe point is 10 mm to 50 mm
A Method for Measuring the Thermal Permeability of Building Glass.
The method according to claim 1,
The normal temperature is a temperature at which the temperature of the building glass and the temperature of the heat source are kept the same
A Method for Measuring the Thermal Permeability of Building Glass.

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