KR102641276B1 - Heated Glass Window System Equipped with Mean Radiant Temperature Controller and Control Method Thereof - Google Patents

Abstract

The present invention relates to a heating glass window system having an average radiant temperature control unit using a temperature sensor that measures the surface temperature of the heating glass and a thermal imaging camera that measures the temperature distribution of infrared reflecting surfaces, including indoor walls, and a control method thereof. Accordingly, the heating glass window system and its control method including the average radiant temperature control unit of the present invention are used to measure the temperature of the indoor wall by using a thermal imaging camera instead of measuring the temperature through a sensor that has the limitation of measuring the temperature at a specific location on the indoor wall. By measuring the temperature of various light reflecting surfaces, including, it is possible to implement a temperature control system that can alleviate radiation imbalance not only in the space adjacent to the window but also in various directions indoors.

Description

Heated glass window system equipped with an average radiant temperature control unit and its control method {Heated Glass Window System Equipped with Mean Radiant Temperature Controller and Control Method Thereof}

The present invention relates to a heating glass window system equipped with an average radiant temperature control unit and a control method thereof. In particular, the present invention relates to a temperature sensor that measures the surface temperature of the heating glass and a temperature distribution of infrared reflecting surfaces including indoor walls. It relates to a heating glass window system equipped with an average radiant temperature control unit using a thermal imaging camera and a method of controlling the same.

Windows are installed in openings such as windows or doorways to block the inside of a building from the outside, and are composed of glass and a frame surrounding it. In particular, the function of windows installed in exterior wall openings is to protect the interior in response to external weather changes, and also serves to block external noise and internal light. In addition, windows are used for indoor ventilation in addition to lighting, view, and soundproofing, and have a structure that can be opened and closed by being coupled to a window frame provided on the wall. This is because when many people stay in a small space indoors in a building such as a house or office, polluted indoor air must be frequently exchanged with fresh outdoor air through ventilation.

Since the glass in windows has a relatively low thermal insulation performance compared to the wall, the surface temperature of the glass in the window is generally lower than that of the wall as well as the interior. In this case, when the indoor relative humidity is 50%, the glass surface temperature of the window is about 10℃ or more lower than the indoor temperature, or when the indoor relative humidity is 70%, the glass surface temperature of the window or door is about 5℃ or more lower than the indoor temperature. Condensation occurs on the glass surface.

Condensation itself is a problem, but the low surface temperature of windows increases the heat loss of occupants through radiant heat transfer, which also reduces indoor thermal comfort performance. As windows, including living room glass, become larger, thermal insulation is especially important in indoor spaces where children or the elderly are present. In many cases, additional measures are necessary. In order to prevent this decrease in heating effect due to glass, heating glass was developed that compensates for the low insulation properties of glass by coating the front of the glass with an electrically conductive heating film to allow current to flow. Such heating glass prevents condensation due to temperature differences between indoors and outdoors in winter, ensures visibility through windows, and helps maintain a comfortable indoor environment by controlling temperature.

In order to prevent condensation and control indoor temperature using heating glass, technology is needed to control the degree of heat generation of the glass by tracking and observing changes in surface temperature of the window and indoor temperature in real time. Republic of Korea Patent No. 10-1233012 is a heating glass system and its control method to prevent condensation, and is equipped with a controller including a heating glass surface temperature sensor and an ambient environment sensor, so that when the surface temperature of the heating glass is lower than or equal to the dew point, Disclosed is a technology for preventing condensation by heating heating glass. However, the environmental sensor can only measure temperature at a fixed location using a temperature sensor or temperature and humidity sensor, and does not consider the temperature of various reflective surfaces, including indoor walls, so there is a problem in that it cannot quantitatively consider the thermal comfort of occupants. .

Republic of Korea Patent No. 10-1233012

The indoor surface temperature of the window is measured using a thermal imaging camera to prevent radiant heat loss from the surrounding indoor surface where the insulation material is installed, and the average radiant temperature of the space adjacent to the window is calculated from this, and the above calculated value is calculated. The purpose of this study is to provide a heating glass window system and its control method equipped with an average radiant temperature control unit that can flow current to the heating glass when the surrounding surface temperature is low.

A heating glass window system equipped with an average radiant temperature control unit, wherein the heating glass control system is: installed as a window in an indoor space, a heating glass coated on one side with a heating film faces the outdoor space, and general glass is placed outside the heating glass. Heating glass part installed; A heating glass unit surface temperature sensing unit located on the surface of the heating glass unit on the indoor space side to detect the surface temperature; A thermal imaging camera unit located between the heating glass unit and the indoor space and measuring the temperature of the light reflecting part of the indoor space by irradiating infrared rays toward the light reflecting part including the wall of the indoor space; Average radiant temperature of the indoor space from the temperature measurement value of the light reflection part of the indoor space of the thermal imaging camera a heating glass temperature control unit that calculates a value and compares the average radiant temperature value of a set indoor space with the calculated average radiant temperature value to control the current value flowing through the heating film coated on the heating glass of the heating glass unit; And a power supply unit that supplies power to the heating film, the surface temperature detection unit, the thermal imaging camera unit, and the temperature control unit, wherein the average radiant temperature is a shape coefficient corresponding to the surface of a plurality of light reflection units in the indoor space, and Function of surface temperature measurements is given as, and the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is The heating film provides a heating glass window system with an average radiant temperature control unit, where the heating film is located on the side facing the general glass.

In the present invention, the heating glass part is arranged from an indoor space into an indoor heating glass and an outdoor general glass, the outdoor general glass is low-e coating glass, and a vacuum or inert gas is formed between the heating glass and the outdoor general glass. Provides a heating glass window system filled with and equipped with an average radiant temperature control unit.

The present invention also provides a heating glass window system including an average radiant temperature control unit, wherein the thermal imaging camera unit scans a light reflection area including a wall of the indoor space with the infrared rays.

The present invention also provides a heating glass window system equipped with an average radiant temperature control unit, in which the heating glass temperature control unit can communicate with a central control room server to enable wired or wireless remote control.

The present invention also provides a control method for a heating glass window system equipped with an average radiant temperature control unit, the control method comprising: a heating film, a surface temperature detection unit, a thermal imaging camera unit, and a power supply unit that supplies power to the heating glass temperature control unit. Step of operating; Heating glass, which is installed as a window in an indoor space and has a heating film coated on one side, faces the indoor space, and uses a surface temperature detection unit of the heating glass unit located on the surface of the indoor space side of the heating glass unit where regular glass is installed outside the heating glass. Sensing the surface temperature of the heating glass unit; It is located in the heating glass part and the indoor space, and includes a wall of the indoor space using a thermal imaging camera unit that measures the temperature of the light reflection part of the indoor space by irradiating infrared rays toward the light reflection part including the wall surface of the indoor space. Measuring the temperature of the light reflection portion; and the average radiant temperature of the indoor space from the temperature measurement value of the light reflection portion of the indoor space of the thermal imaging camera. Calculating a value, comparing the average radiant temperature value of the set indoor space with the calculated average radiant temperature value, and controlling the current value flowing through the heating film coated on the heating glass of the heating glass unit with the heating glass temperature control unit. , the average radiant temperature is a function of the shape coefficient and surface temperature measurement value corresponding to the surface of the plurality of light reflection units in the indoor space. is given as, and the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is In addition, the heating film provides a control method of a heating glass window system including an average radiant temperature control unit, where the heating film is located on the side facing the general glass.

In the present invention, the heating glass part is composed of an indoor heating glass and an outdoor glass part, wherein the heating coating part of the indoor heating glass is directed toward the outdoor side, and the outdoor glass part is designed to minimize the movement of the heat generation of the heating glass to the outdoor side. For this purpose, glass with excellent thermal insulation performance, such as low-e coating glass, is used. A heating glass window system is provided with an average radiant temperature control unit, which is arranged in the order of heating glass and outdoor general glass from an indoor space, and between the heating glass and the outdoor general glass is filled with a vacuum or inert gas.

The present invention also provides a control method of a heating glass window system including an average radiant temperature control unit, wherein the thermal imaging camera unit scans a light reflection area including a wall of the indoor space with the infrared rays.

The present invention also provides a method of controlling a heating glass window system including an average radiant temperature control unit, wherein the heating glass temperature control unit can communicate with a central control room server to enable wired or wireless remote control.

The heating glass window system and its control method including the average radiant temperature control unit of the present invention include the indoor wall surface by using a thermal imaging camera rather than measuring the temperature through a sensor that has the limitation of measuring the temperature at a specific location on the indoor wall surface. By measuring the temperature of various light reflecting surfaces, a temperature control system that can alleviate radiation imbalance not only in the space adjacent to the window but also in various directions indoors can be implemented.

Figure 1 shows the average radiant temperature calculated using temperature data and thermal image data from the surface temperature sensor and thermal imaging camera of the measuring unit, according to an embodiment of the present invention, compared to a set value to supply power to the heating glass, which is the operating unit. This is a conceptual diagram showing a control system that operates.
Figure 2 is a conceptual diagram showing a heating glass window equipped with a surface temperature sensor for measuring the surface temperature of the heating glass and a thermal imaging camera for measuring the temperature of the indoor light-reflecting wall surface, according to an embodiment of the present invention.
Figure 3 is a conceptual diagram of a structure for calculating an average radiant temperature using the temperature of an indoor light reflecting surface and a shape coefficient corresponding to the surface, according to an embodiment of the present invention.
Figure 4 is a conceptual diagram showing the location of surface input parameters for calculating the shape coefficient of an indoor light reflective surface, according to an embodiment of the present invention.
Figure 5 is a conceptual diagram showing a control flow chart of a heating glass window system equipped with an average radiant temperature control unit according to an embodiment of the present invention.
Figure 6 is a conceptual diagram showing the configuration of a heating glass portion of a heating glass window system according to an embodiment of the present invention.

In the description below, for purposes of explanation, numerous specific details are set forth to facilitate a general understanding of one or more aspects. However, it should be recognized that these aspects can be implemented without individual specific details. The following description and accompanying drawings set forth in detail certain example aspects of one or more aspects. However, these aspects are illustrative and some of the various methods may be used in accordance with the principles of the various aspects and the written description is intended to encompass all such aspects and their equivalents.

Various aspects and features may be presented by a system that may include multiple devices, modules, etc. It should also be understood and appreciated that various systems may include additional devices, parts, components, etc. and/or may not include all of the devices, parts, components, etc. discussed in connection with the drawings.

As used herein, “embodiments,” “examples,” “aspects,” “examples,” etc. should not be construed to mean that any aspect or design described is better or advantageous over other aspects or designs. The terms used below, such as 'database', 'server', 'input unit', and 'output unit', generally refer to computer-related entities, such as hardware, a combination of hardware and software, and software. It can mean.

Additionally, the term “or” is intended to mean an inclusive “or” and not an exclusive “or.” That is, unless otherwise specified or clear from context, “X utilizes A or B” is intended to mean one of the natural implicit substitutions. That is, either X uses A; X uses B; Or, if X uses both A and B, “X uses A or B” can be applied to either of the above cases. Additionally, the term “and/or” as used herein should be understood to refer to and include all possible combinations of one or more of the related listed items.

Additionally, the terms “comprise” and/or “comprising” mean that the feature, step, operation, module, and/or component is present, but one or more other features, steps, operations, modules, or components are present. It should be understood that this does not exclude the presence or addition of elements, and/or groups. In addition, although terms such as first and second may be used in this specification to describe various components, these components are not limited by these terms. That is, these terms are only used to distinguish between two or more components and should not be interpreted to imply order or priority. Additionally, unless otherwise specified or the context is clear to indicate a singular form, the singular terms herein and in the claims should generally be construed to mean “one or more.” Hereinafter, embodiments of the present invention will be described with reference to the attached drawings.

Figure 1 shows the average radiant temperature calculated using temperature data and thermal image data from the surface temperature sensor and thermal imaging camera of the measuring unit, according to an embodiment of the present invention, compared to a set value to supply power to the heating glass, which is the operating unit. Figure 2 is a conceptual diagram showing a control system, and Figure 2 is a heating glass window equipped with a surface temperature sensor that measures the surface temperature of the heating glass and a thermal imaging camera that measures the temperature of the indoor light-reflecting wall surface, according to an embodiment of the present invention. This is a concept diagram representing . The present invention is a heating glass window system with an average radiant temperature control unit, which is installed as a window in an indoor space, and a heating glass coated on one side with a heating film faces the indoor space and regular glass is installed outside the heating glass. wealth; A heating glass unit surface temperature sensing unit located between the heating glass unit and the indoor space to detect surface temperature; A thermal imaging camera unit located between the heating glass unit and the indoor space and measuring the temperature of the light reflecting part of the indoor space by irradiating infrared rays toward the light reflecting part including the wall of the indoor space; Average radiant temperature of the indoor space from the temperature measurement value of the light reflection part of the indoor space of the thermal imaging camera a heating glass temperature control unit that calculates a value and compares the average radiant temperature value of a set indoor space with the calculated average radiant temperature value to control the current value flowing through the heating film coated on the heating glass of the heating glass unit; and a power supply unit that supplies power to the heating film, the surface temperature detection unit, the thermal imaging camera unit, and the temperature control unit. In one embodiment of the present invention, a plurality of thermal imaging cameras located between the heating glass unit and the indoor space may be located on the surface of the heating glass unit, a boundary between the heating glass and the indoor space, and the indoor space, and may be positioned in a measurement direction. It can be adjusted. In one embodiment of the present invention, the wall surface where infrared rays from the thermal imaging camera are reflected in the indoor space becomes the surface of the light reflection unit, and the surface of the light reflection unit is measured under the same temperature condition according to various variables such as its material and surface roughness. Since the values may differ, this error can be corrected using the shape factor. All light reflector surfaces in the room are required for calculation, but light reflector surfaces that are not within the thermal imaging camera's identification range can be replaced by other light reflector surfaces that are within the identification range.

In one embodiment of the present invention, the heating glass part is composed of indoor heating glass and outdoor regular glass or outdoor low-E glass, and is arranged in the order of heating glass and outdoor regular glass from the indoor space, and the heating glass and the outdoor regular glass. The space between ordinary glass can be filled with vacuum or inert gas for insulation. In one embodiment of the present invention, the thermal imaging camera unit may scan a light reflecting portion including a wall of the indoor space with the infrared rays.

Figure 3 is a conceptual diagram of a structure for calculating the average radiant temperature using the temperature of an indoor light reflecting surface and the shape coefficient corresponding to the surface, according to an embodiment of the present invention, and Figure 4 is an embodiment of the present invention. This is a conceptual diagram showing the location of surface input parameters for calculating the shape coefficient of an indoor light reflecting surface. In one embodiment of the present invention, the average radiant temperature is a function of the shape coefficient and surface temperature measurements corresponding to the surfaces of a plurality of light reflection units in an indoor space. is given as, and the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is and the heating film is located on the side facing the general glass. In one embodiment of the present invention, the heating glass temperature control unit is capable of communicating with a central control room server to enable wired or wireless remote control. Shape factor in one embodiment of the present invention is the target point A specific surface compared to the total radiant energy radiated from It is calculated using the geometric relationship with the surface as a ratio to the radiant energy incident on it.

Figure 5 is a conceptual diagram showing a control flow chart of a heating glass window system equipped with an average radiant temperature control unit according to an embodiment of the present invention. In another embodiment, the present invention is a control method of a heating glass window system equipped with an average radiant temperature control unit, which operates a power supply unit that supplies power to the heating film, surface temperature detection unit, thermal imaging camera unit, and heating glass temperature control unit. steps; Heating glass, which is installed as a window in an indoor space and has a heating film coated on one side, faces the indoor space, and uses a surface temperature detection unit of the heating glass unit located on the surface of the indoor space side of the heating glass unit where regular glass is installed outside the heating glass. Sensing the surface temperature of the heating glass unit; A thermal imaging camera unit is located adjacent to the indoor space side of the heating glass unit and measures the temperature of the light reflecting part of the indoor space by irradiating infrared rays toward the light reflecting part including the wall surface of the indoor space to measure the temperature of the light reflecting part of the indoor space. Measuring the temperature of the light reflection unit included; and the average radiant temperature of the indoor space from the temperature measurement value of the light reflection portion of the indoor space of the thermal imaging camera. Calculating the value, comparing the average radiant temperature value of the set indoor space with the calculated average radiant temperature value, and controlling the current value flowing through the heating film coated on the heating glass of the heating glass unit with the heating glass temperature control unit. .

In one embodiment of the present invention, the average radiant temperature is a function of the shape coefficient and surface temperature measurements corresponding to the surfaces of a plurality of light reflection units in an indoor space. Given, the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is and the heating film is located on the side facing the general glass. In one embodiment of the present invention, the heating glass part is composed of an indoor heating glass and an outdoor glass part, and are arranged in the order of heating glass and outdoor general glass from the indoor space, and a vacuum is formed between the heating glass and the outdoor general glass. Or, it is filled with an inert gas, and the thermal imaging camera unit scans the light reflecting part including the wall of the indoor space with the infrared rays, and the heating glass temperature control unit enables wired and wireless remote control, and the central control room server It is possible to communicate with.

Figure 6 is a conceptual diagram showing the configuration of the heating glass part of the heating glass window system. The heating glass part is composed of an indoor heating glass and an outdoor glass part. The heating coating part of the indoor heating glass faces the outdoor side, and the outdoor glass part generates heat. In order to minimize the transfer of heat generation from glass to the outdoor side, glass with excellent thermal insulation performance, such as low-e coating glass or vacuum glass, is used. They are arranged in order from the indoor space to the heating glass and the outdoor general glass, and the space between the heating glass and the outdoor general glass is filled with a vacuum or inert gas.

In one implementation of the present invention, the control logic can be controlled through the following process.

(1) When the system is activated, the thermal imaging camera collects thermal image data of indoor surfaces and transmits the collected data to the control system.

(2) The control system determines the current average radiant temperature based on the thermal image data transmitted using an internal function and the detection data from the surface temperature sensor installed on the window surface.

- Average radiation temperature calculation function

Average radiation temperature is the temperature of the surrounding surface and the shape coefficient corresponding to the corresponding surface It is calculated using . (Equation 1, Figure 3) Here, the shape coefficient is a geometric ratio to the radiant energy radiated from a target point to a specific surface and is calculated using the geometric relationship with the surface. (Equation 2, Figure 4)

- Equation 1)

- Equation 2)

(3) If the calculated current average radiant temperature is lower than the set average radiant temperature, power is applied to the heating glass and operated to satisfy the determined set temperature.

(4) If the current average radiation temperature is equal to or higher than the set average radiation temperature, return to (1) and repeat the subsequent process.

Although the exemplary embodiments of the present application have been described in detail above, the scope of the rights of the present application is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present application defined in the following claims are also included in the scope of the rights of the present application. belongs to

All technical terms used in the present invention, unless otherwise defined, are used with the same meaning as commonly understood by a person skilled in the art in the field related to the present invention. The contents of all publications incorporated by reference herein are hereby incorporated by reference.

Claims (8)

A heating glass window system equipped with an average radiant temperature control unit, the heating glass window system includes:
A heating glass unit installed as a window of an indoor space, in which heating glass coated on one side with a heating film faces the indoor space, and regular glass is installed outside the heating glass;
A heating glass unit surface temperature sensing unit located on the surface of the heating glass unit on the indoor space side to detect the surface temperature;
A thermal imaging camera unit located between the heating glass unit and the indoor space and measuring the temperature of the light reflecting part of the indoor space by irradiating infrared rays toward the light reflecting part including the wall of the indoor space;
Average radiant temperature of the indoor space from the temperature measurement value of the light reflection part of the indoor space of the thermal imaging camera a heating glass temperature control unit that calculates a value and compares the average radiant temperature value of a set indoor space with the calculated average radiant temperature value to control the current value flowing through the heating film coated on the heating glass of the heating glass unit; and
It includes a power supply unit that supplies power to the heating film, the surface temperature detection unit, the thermal imaging camera unit, and the temperature control unit,
The average radiant temperature is a function of the shape coefficient and surface temperature measurement value corresponding to the surface of a plurality of light reflection units in the indoor space. is given as, and the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is and
The heating film is located on the side facing the general glass,
Heated glass window system with average radiant temperature control unit.
According to claim 1,
The heating glass part is arranged from the indoor space into indoor heating glass and outdoor regular glass, and the outdoor regular glass is low-e coating glass,
Between the heating glass and the outdoor general glass is filled with a vacuum or inert gas,
Heated glass window system with average radiant temperature control unit.
According to clause 1,
The thermal imaging camera unit scans a light reflection area including a wall of the indoor space with the infrared rays,
Heated glass window system with average radiant temperature control unit.
According to clause 1,
The heating glass temperature control unit is capable of communicating with the central control room server to enable wired and wireless remote control,
Heated glass window system with average radiant temperature control unit.
A control method for a heating glass window system equipped with an average radiant temperature control unit, the control method is:
Operating a power supply unit that supplies power to the heating film, surface temperature detection unit, thermal imaging camera unit, and heating glass temperature control unit;
Heating glass, which is installed as a window in an indoor space and has a heating film coated on one side, faces the indoor space, and uses a surface temperature detection unit of the heating glass unit located on the surface of the indoor space where regular glass is installed outside the heating glass. Sensing the surface temperature of the heating glass unit;
It is located in the heating glass part and the indoor space, and includes a wall of the indoor space using a thermal imaging camera unit that measures the temperature of the light reflection part of the indoor space by irradiating infrared rays toward the light reflection part including the wall surface of the indoor space. Measuring the temperature of the light reflection portion; and
Average radiant temperature of the indoor space from the temperature measurement value of the light reflection part of the indoor space of the thermal imaging camera Calculating a value, comparing the average radiant temperature value of the set indoor space with the calculated average radiant temperature value, and controlling the current value flowing through the heating film coated on the heating glass of the heating glass unit with the heating glass temperature control unit. ,
The average radiant temperature is a function of the shape coefficient and surface temperature measurement value corresponding to the surface of a plurality of light reflection units in the indoor space. is given as, and the shape coefficient corresponding to the surface of the jth light reflection part in the indoor space is And the surface temperature measurement value of the jth light reflection part of the indoor space is and
The heating film is located on the side facing the general glass,
Control method of a heating glass window system equipped with an average radiant temperature control unit.
delete According to clause 5,
The thermal imaging camera unit scans a light reflection area including a wall of the indoor space with the infrared rays,
Control method of a heating glass window system equipped with an average radiant temperature control unit.
According to clause 5,
The heating glass temperature control unit is capable of communicating with the central control room server to enable wired and wireless remote control,
Control method of a heating glass window system equipped with an average radiant temperature control unit.