KR101551723B1 - Control System of Input Quantity of Heat for Heating Glass Window and Method thereof - Google Patents

Abstract

The present invention relates to an automatic control method of heat supply for a heating glass window, wherein the automatic control method may include: a first step of measuring interior and exterior temperatures by using a thermometer provided on a heating glass window, and providing a temperature comparing unit with the temperature information; a second step of providing a power supply calculating unit with the interior and exterior temperature difference information when the interior temperature is higher than the exterior temperature in the temperature comparing unit provided with the temperature information in the first step; and a third step of calculating the heat loss of the window by using the temperature difference information, calculating an anti-condensation power supply by multiplying the heat loss by an energy conversion efficiency coefficient, and providing a power control unit with the anti-condensation power supply information; and a fourth step of controlling the supply of power corresponding to the anti-condensation power supply to the heating glass window. By minimizing variables for automatically controlling the heating glass window, the present invention automatically and variably controls the minimum power as a result of the exterior and interior temperature difference only as much as the heat loss based on the area and heat perfusion rate of the window including the glass and the frame. Therefore, less electrical energy is consumed, and heat loss and condensation with respect to the entire window are prevented.

Description

Technical Field [0001] The present invention relates to a control system for a heating glass window,

The present invention relates to a method for controlling the amount of heat to be supplied to a heat-resistant glass window, and more particularly, to a method for controlling the amount of heat supplied to an exothermic glass To a method of automatically controlling the amount of heat supplied to a window.

A window is a window formed in an opening of a window or an entrance to block the inside of the building from the outside. The window is mainly composed of a glass and a frame surrounding the window. In particular, the function of a window installed in the opening of the outer wall is to protect the room in response to an external weather change, and it also serves to block external noise and internal light.

Since the glass of a window has a relatively low adiabatic performance compared to a wall, the temperature of the glass surface of the window is generally lower than that of the room and the wall. In this case, when the relative humidity of the room is 50%, the glass surface temperature of the window is lower than the room temperature by about 10 ° C or the indoor relative humidity is 70%, if the glass surface temperature of the window is lower than the room temperature by about 5 ° C or more Condensation occurs on the glass surface.

Condensation itself is a problem, but the heating effect of the room is lowered due to the heat escaping through the glass. As the windows including the living room glass are getting bigger, there is often a need for additional measures for keeping warm in the indoor space where there are children or elderly people. In order to prevent the heating effect and condensation from occurring, a heating glass is developed that coats the entire surface of the glass with a heating film having electrical conductivity to flow current to the heating film, thereby heating the glass surface to complement the heat insulating property of the glass.

In a system employing such a heat-generating glass, the temperature of the heat-generating glass is maintained at a predetermined temperature or more to prevent the formation of condensation in the weather where the outdoor temperature is lowered. There is a problem that a large amount of power is consumed in order to maintain a constant temperature by supplying electric power to the heat-generating glass. In order to solve this problem, Korean Patent Laid-Open Publication No. 2011-0074199 discloses a method of measuring a temperature by attaching a temperature sensor on the surface of a room heat-generating glass, calculating a dew point from the separately measured room temperature and humidity, A method of controlling power of a heating glass for supplying power is disclosed.

However, the method of calculating the dew point and automatically controlling the amount of power supplied to the heating glass has many variables such as room temperature, humidity, and relative humidity. If the glass surface temperature is higher than the dew point, the heating function is not operated. May be maintained at a low level. In addition, although such a control method can prevent condensation of the window glass itself, it also has a limitation that condensation may still occur in the window glass.

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Korea Patent Publication No. 2011-0074199

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to simplify a control structure by minimizing a variable for automatic control of a heat-resistant glass window, to prevent condensation on a glass part, And provides a method for controlling power supply.

In order to solve the above problems, the present invention has been accomplished by minimizing the parameters for automatic control of the heat-resistant glass windows to simplify the control structure and supplying the heat through the heat-generating glass as much as the heat escaping from the windows.

The present invention provides a method for automatically controlling the amount of heat supplied to an exothermic glass window, wherein the automatic control method includes a first step of providing a temperature comparator with temperature information by measuring a room temperature and an outdoor temperature using a temperature measuring instrument provided in the heat- step; A second step of providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first step; Calculating a loss heat quantity of the window by using the temperature difference information, multiplying the loss heat quantity by an energy conversion efficiency coefficient to calculate a dew condensation preventing power supply amount, A third step of providing condensation prevention power supply amount information to the power supply control unit; And a fourth step of controlling, in a power supply control unit provided with the dew condensation preventing power supply amount information in the third step, to supply power corresponding to the dew condensation preventing power supply amount to the heat generating glass .

The present invention is characterized in that the third step further comprises the step of calculating the additional power supply amount information required for the heating supply calorie amount level by the power supply amount calculating unit in accordance with a predetermined heating calorific value for heating and providing the additional power supply amount information to the power supply control unit The method comprising the steps of:

The present invention also provides a method for automatically controlling the calorific value of the calorific glass window provided in the calorific glass window, wherein the distance between the calorimeter and the glass surface is 1 to 30 cm.

The present invention also provides a method for automatically controlling the amount of furnace calorie supply heat, wherein the loss heat quantity of the window is represented by the following equation (1) and the dew condensation preventing power supply amount is represented by the following equation (2).

[Equation 1]

Q (heat loss) = U (intrinsic heat conduction rate of heat-resistant glass window frame) × A (area of window) × ΔT (difference in indoor / outdoor temperature)

[Equation 2]

Qsup (minimum power supply) = Qloss (heat loss of window) x (energy conversion efficiency coefficient)

(In the above equation 2,

ε (Energy Conversion Efficiency Factor) = Inverse of the inherent energy conversion efficiency value of heat glass × 1.1).

The present invention is also characterized in that the predetermined heating power supply heating level is at least one, one level, and two or more levels, and the additional power supply amount corresponding to the second level of the heating power supply is twice as high as the first additional power supply amount, Provides a method for automatically controlling the calorific value of the glass window.

According to another aspect of the present invention, there is provided a system for automatically controlling the amount of heat supplied to an exothermic glass window, the system comprising: a temperature gauge provided in the exothermic glass window arc to measure a room temperature and an outdoor temperature and provide temperature information to the temperature comparator; A temperature comparator for calculating indoor / outdoor temperature difference information when the indoor temperature is higher than the outdoor temperature using the temperature information provided by the temperature measuring device and providing the indoor / outdoor temperature difference information to a power supply amount calculator; A power supply quantity calculator for calculating a loss heat quantity of the window by using the temperature difference information provided by the temperature comparator, calculating the dew condensation preventing power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient, A power supply controller for supplying power to the heat generating glass corresponding to the dew condensation preventing power supplied from the power supply calculating unit; And a control unit for controlling sequential operations of the temperature meter, the temperature comparator, the power supply amount calculator, and the power supply control unit.

The present invention also relates to a computer readable medium for automatic control of calorific power supply to an exothermic glass window, the computer readable medium storing instructions for causing a computer to perform the following operations: A first operation for providing the temperature information to the temperature comparator by measuring the room temperature and the outdoor temperature using a temperature meter provided in the call; A second operation for providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first operation; The power supply quantity calculator provided with the temperature difference information in the second operation calculates the loss heat quantity of the window by using the temperature difference information, calculates the anti-condensation power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient, A third operation for providing condensation preventing power supply amount information to the power supply control unit; And a fourth operation for controlling the power supply control unit to receive the dew condensation preventing power supply amount in the third operation so as to supply power corresponding to the dew condensation preventing power supply amount to the heat generating glass, ≪ / RTI >

The present invention minimizes the parameters for automatic control of the heat-resistant glass windows and automatically controls and supplies the minimum power according to the difference between the indoor and outdoor temperatures only by the amount of heat loss based on the window heat-flow rate and area including the glass and the window frame It consumes less electric energy, and is effective in preventing heat loss to the entire window and preventing condensation.

1 is a flowchart showing the steps of a control method of the present invention.
2 is a schematic diagram showing the difference between the room temperature in the center of the room and the room temperature in the vicinity of the window.
Fig. 3 is a schematic diagram showing the range of the temperature measurement.
4 is a schematic diagram showing the sensing element for preventing heat loss and condensation.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Prior to the detailed description of the present invention, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

Here, in the entire drawings for explaining the embodiments of the present application, those having the same functions are denoted by the same reference numerals, and a detailed description thereof will be omitted.

1 is a flowchart showing the steps of a control method of the present invention. A method of automatically controlling an amount of heat supplied to an exothermic glass window, the method comprising: a first step of providing temperature information to a temperature comparator by measuring a room temperature and an outdoor temperature using a temperature meter provided in the exothermic glass window; A second step of providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first step; Calculating a loss heat quantity of the window by using the temperature difference information, multiplying the loss heat quantity by an energy conversion efficiency coefficient to calculate a dew condensation preventing power supply amount, A third step of providing condensation prevention power supply amount information to the power supply control unit; And a fourth step of controlling, in the power supply control unit provided with the dew condensation preventing power supply amount information in the third step, to supply power corresponding to the dew condensation preventing power supply amount to the heat generating glass.

As shown in FIG. 2, since the room temperature and the outdoor temperature are different from the air temperature near the window and the air temperature at the indoor center, and the humidifier that directly affects the condensation corresponds to the air around the window near the window, And zero heat exchange between outdoor air temperature to prevent heat loss and prevent condensation. Accordingly, in an embodiment of the present invention, the distance between the temperature measuring instrument and the glass surface is 1 to 30 cm, and the measuring instrument is provided in the heating glass window, and the measuring range is shown in FIG. The temperature difference standard between the indoor air and the outdoor air is a difference between the outdoor air temperature and the indoor temperature.

In the first step, the indoor temperature and the outdoor temperature are measured using the temperature measuring device provided in the heating window. In the second step, the temperature information provided in the first step is stored in the temperature comparator so that the outdoor temperature is higher than the room temperature If the room temperature is higher than the outdoor temperature, the indoor / outdoor temperature difference information is provided to the electric power supply quantity calculator. In the third step, the power supply quantity calculator provided with the temperature difference information calculates the heat loss amount of the window using the temperature difference information, and calculates the dew condensation preventing power supply amount by multiplying the heat loss conversion coefficient by the energy conversion efficiency coefficient. If the temperature is higher than the room temperature, the power supply is set to be cut off. The heat loss amount of the window is calculated by Q (loss heat quantity) = U (the intrinsic heat conduction rate of the frame including the frame) × A (area of the window) × ΔT And the supply power amount is calculated by multiplying the conversion efficiency coefficient. The energy conversion efficiency coefficient is (inverse number of energy conversion efficiency) x 1.1, and 1.1 is a safety factor for reducing the possibility of heat loss.

Energy conversion efficiency means that the amount of heat supplied from the heat-generating glass does not escape to the outside depending on the composition of the window (multi-layered / triple-layered, general / Efficiency, and an example of calculation of the energy conversion efficiency coefficient is shown in Table 1.

[Table 1] Example of calculation of energy conversion efficiency coefficient

In the present invention, the double-layered glass is made to have a dry air layer using at least two sheet glass and a spacer, and it has an excellent effect of preventing heat insulation and condensation by reducing the amount of heat energy escaping through the window. Especially, the effect of insulation is excellent, so it is possible to save the heating cost and to express the individuality of the building according to the color of the disc as well as the effect of noise reduction.

The two-layer glass manufacturing process is accomplished by applying a gimp, a first-order adhesive, and a hygroscopic agent to two well-cleaned glasses. Since the double-layered glass generally has twice the heat insulating property than that using one piece of glass, it is excellent in heat insulation because it reduces cooling and heating (especially heating) load. In order to improve the function of the double-layered glass, the application of the double-layered glass with the roycasting glass having excellent heat insulation effect is given the highest priority and the gas (argon and krypton) is injected into the dry air layer between the glass and the glass to maximize the heat insulation effect Multilayer glass is a necessary part of enhancing the function of the multilayer glass.

Especially, the gap between glass and glass in double layered glass has a great influence on the adiabatic effect. In Korea, double layer glass products using 6mm air layer are mostly used, but 6mm is most suitable distance to transfer cold air. Even if glass is thinned, taking air layer thick is effective for insulation.

In addition, the triple glazing has two air layers in the form of adding two sheets of existing glass plates to each other with the intermediate bar interposed therebetween, thereby achieving high sound insulation performance. In addition, the outer wall glass of the building is made of silver (Ag) coating (low-e) on the glass surface to ensure the optimal high heat insulation. Generally, it is manufactured for two purposes. And the heat insulation property is greatly improved.

Low-e glass in a double-layer glass is a glass coated with a special metallic film (usually silver) with a high infrared reflectance inside a general glass. It is a glass that enhances the insulation performance of a building. A special metal film transmits visible light It is an energy-saving glass that minimizes the indoor temperature change by minimizing the indoor and outdoor heat movement because it reflects the infrared light and improves the indoor light-emitting property. Since Roy's double-layer glass is coated with a special metal film having excellent heat insulation effect on the plate glass, .

The emissivity of Roye glass is much lower than the emissivity of blackbody and plate glass, which is good for adiabatic energy saving energy by 32% compared to plate glass and 6% compared to double glass. In the case of a commercial building where summer cooling is important, a loose double-glazed glass with a special metal film on the outdoor side glass is advantageous to prevent outdoor solar radiation from entering the room. In the case of a residential building where winter heating is emphasized, It is advantageous to use a double layer glass with a special metal film on the indoor side glass to reflect the infrared rays generated in the indoor side. Regardless of the season, both glass can be coated with a special metal film for superior insulation performance in the room. The advantage of ROYE glass is its high visible light transmittance, excellent indoor light effect and high insulation performance, it can reduce heating cost in winter. In combination with double layer glass, it has excellent insulation effect in winter with 30% , It is possible to provide a comfortable indoor environment by interrupting the unpleasant cold radiation around the winter window.

In the fourth step of supplying power corresponding to the dew condensation preventing power supply amount to the heat generating glass in the power supply controller provided with the dew condensation preventing power supply amount information in the third step, the dew condensation preventing power supply amount is Qsup (minimum power supply amount) = Is calculated as Qloss (heat loss amount of window) x (energy conversion efficiency coefficient).

The step 3 further includes a step of calculating the additional power supply amount information required by the heating supply calorie level at the power supply amount calculating unit according to a predetermined heating calorific value for heating and providing the additional power supply amount information to the power supply control unit, The amount of heating power supplied for heating is one, none, one level, and two or more levels, and the additional power supply amount corresponding to the second level power supply amount is twice as much as the first additional power supply amount.

As shown in FIG. 3, the present invention has simplified the sensing element for automatic control to two types of indoor / outdoor air temperature, and it is possible to reduce the heat loss and the area of the window including the window and the window, The power consumption is only 22.6Wh / m² even when the temperature difference between the inside and the outside is 20 ° C as shown in Table 2. According to the experimental results, it was confirmed that when the conventional temperature setting control method is used, energy of about 60 Wh / m 2 is consumed in order to set and maintain the surface temperature of 20 ° C at the outdoor temperature of 8 ° C and the room temperature of 18 ° C. That is, since the power consumption of 60 Wh / m² or more is consumed at a temperature difference of 10 ° C. or more between the inside and the outside, it is ineffective from the viewpoint of energy efficiency, but it is an effective method in terms of energy efficiency.

[Table 2] Power consumption during automatic control of heating calorie supply

According to another aspect of the present invention, there is provided an automatic control system for supplying heat to a heating glass window, the system comprising: a temperature measuring unit provided in the heating glass window for measuring a room temperature and an outdoor temperature and providing temperature information to the temperature comparator; A temperature comparator for calculating indoor / outdoor temperature difference information when the indoor temperature is higher than the outdoor temperature using the temperature information provided by the temperature measuring device and providing the indoor / outdoor temperature difference information to a power supply amount calculator; A power supply quantity calculator for calculating a loss heat quantity of the window by using the temperature difference information provided by the temperature comparator, calculating the dew condensation preventing power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient, A power supply controller for supplying power to the heat generating glass corresponding to the dew condensation preventing power supplied from the power supply calculating unit; And a controller for controlling the sequential operation of the temperature meter, the temperature comparator, the power supply amount calculator, and the power supply control unit.

The temperature measuring device and the temperature comparator can be installed anywhere inside or outside the heating glass and the frame of the heating window.

The present invention also relates to a computer readable medium for automatic calorie control of an exothermic glass window, the computer readable medium storing instructions for causing a computer to perform the following operations: A first operation for providing the temperature information to the temperature comparator by measuring the room temperature and the outdoor temperature using a temperature meter provided in the call; A second operation for providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first operation; The power supply quantity calculator provided with the temperature difference information in the second operation calculates the loss heat quantity of the window by using the temperature difference information, calculates the anti-condensation power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient, A third operation for providing condensation preventing power supply amount information to the power supply control unit; And a fourth operation for controlling the power supply controller to receive the dew condensation prevention power supply amount information in the third operation so as to supply power corresponding to the dew condensation prevention power supply amount to the heat generating glass. The instructions stored in the computer-readable recording medium capable of performing the above operations operate optimally in the system, but can also be executed in other apparatuses containing the same.

While the present invention has been described in connection with what is presently considered to be the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, .

All technical terms used in the present invention are used in the sense that they are generally understood by those of ordinary skill in the relevant field of the present invention unless otherwise defined. The contents of all publications referred to herein are incorporated herein by reference.

Claims (7)

Heating glass window As an automatic control method of heating calorie supply,
The automatic control method may include: a first step of providing temperature information to a temperature comparator by measuring a room temperature and an outdoor temperature using a temperature meter provided in the heating glass window call;
A second step of providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first step;
Calculating a loss heat quantity of the window by using the temperature difference information, multiplying the loss heat quantity by an energy conversion efficiency coefficient to calculate a dew condensation preventing power supply amount, A third step of providing condensation prevention power supply amount information to the power supply control unit; And
And a fourth step of controlling, in the power control unit provided with the dew condensation preventing power supply amount information in the third step, to supply power corresponding to the dew condensation preventing power supply amount to the heat generating glass,
The heat loss amount of the window is expressed by the following equation 1,
The dew condensation preventing power supply amount is calculated by the following equation (2)
Heating window glass Automatic control of furnace heat supply method:
[Equation 1]
Q (heat loss) = U (intrinsic heat conduction rate of heat-resistant glass window frame) × A (area of window) × ΔT (difference in indoor / outdoor temperature)

[Equation 2]
Qsup (minimum power supply) = Qloss (heat loss of window) x (energy conversion efficiency coefficient)
(In the above equation 2,
ε (Energy Conversion Efficiency Factor) = Inverse of the inherent energy conversion efficiency value of heat glass × 1.1).
The method according to claim 1,
In the third step,
Further comprising the step of calculating the additional power supply amount information required by the heating supply calorie amount level in the power supply amount calculating unit according to a predetermined heating calorific value for heating and providing the additional power supply amount information to the power supply control unit.
Automatic control method of calorific value of heating glass window arc.
The method according to claim 1,
The distance between the temperature meter and the glass surface is 1 to 30 cm,
Wherein the measuring device comprises:
Automatic control method of calorific value of heating glass window arc.
delete 3. The method of claim 2,
The predetermined heating calorific value for heating,
None, one level, and two or more levels,
Wherein the additional power supply amount corresponding to the second-level supply heat amount is twice the first-level additional power supply amount,
Automatic control method of calorific value of heating glass window arc.
Heating window glass Automatic supply control system,
The system comprising: a temperature measuring unit provided in the heating glass window for measuring a room temperature and an outdoor temperature and providing temperature information to the temperature comparator;
A temperature comparator for calculating indoor / outdoor temperature difference information when the indoor temperature is higher than the outdoor temperature using the temperature information provided by the temperature measuring device and providing the indoor / outdoor temperature difference information to a power supply amount calculator;
A power supply quantity calculator for calculating a loss heat quantity of the window by using the temperature difference information provided by the temperature comparator, calculating the dew condensation preventing power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient,
A power supply controller for supplying power to the heat generating glass corresponding to the dew condensation preventing power supplied from the power supply calculating unit; And
A temperature comparator, a power supply amount calculator, and a power supply control unit,
The heat loss amount of the window is expressed by the following equation 1,
The dew condensation preventing power supply amount is calculated by the following equation (2)
Heating window glass supply Calorie automatic control system:
[Equation 1]
Q (heat loss) = U (intrinsic heat conduction rate of heat-resistant glass window frame) × A (area of window) × ΔT (difference in indoor / outdoor temperature)

[Equation 2]
Qsup (minimum power supply) = Qloss (heat loss of window) x (energy conversion efficiency coefficient)
(In the above equation 2,
ε (Energy Conversion Efficiency Factor) = Inverse of the inherent energy conversion efficiency value of heat glass × 1.1).
Heat window glass A computer-readable medium for automatically controlling the supply of heat,
The computer readable medium storing instructions for causing a computer to perform the following operations:
A first operation for measuring a room temperature and an outdoor temperature using a temperature meter provided in the heating window and providing temperature information to the temperature comparator;
A second operation for providing the indoor / outdoor temperature difference information to the power supply amount calculator when the indoor temperature is higher than the outdoor temperature in the temperature comparator provided with the temperature information in the first operation;
The power supply quantity calculator provided with the temperature difference information in the second operation calculates the loss heat quantity of the window by using the temperature difference information, calculates the anti-condensation power supply quantity by multiplying the loss heat quantity by the energy conversion efficiency coefficient, A third operation for providing condensation preventing power supply amount information to the power supply control unit; And
And a fourth operation for controlling the power supply controller to receive the dew condensation preventing power supply amount information in the third operation so as to supply power corresponding to the dew condensation preventing power supply amount to the heat generating glass,
The heat loss amount of the window is expressed by the following equation 1,
The dew condensation preventing power supply amount is calculated by the following equation (2)
Generating a heat window glass Computer-readable medium for automatic calorimetric control:
[Equation 1]
Q (heat loss) = U (intrinsic heat conduction rate of heat-resistant glass window frame) × A (area of window) × ΔT (difference in indoor / outdoor temperature)

[Equation 2]
Qsup (minimum power supply) = Qloss (heat loss of window) x (energy conversion efficiency coefficient)
(In the above equation 2,
ε (Energy Conversion Efficiency Factor) = Inverse of the inherent energy conversion efficiency value of heat glass × 1.1).

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