KR20100011181A - Window system having heating means - Google Patents

Abstract

PURPOSE: A window system with a heating device is provided to effectively prevent dew condensation caused by the difference between the indoor temperature and the outside temperature. CONSTITUTION: A window system with a heating device comprises a window case frame(100), window frames(210,220), and window glasses(310,320). A power-up device is installed in the window case frame. Window frames are movably installed in the window case frame. A power supply device is installed in the window frames. The window glasses are installed in the window frames. A heating device is installed in the window glasses.

Description

Window system having heating means

The present invention relates to a window system, and more particularly to a window system having a structure capable of suppressing the occurrence of condensation on the indoor corresponding surface of the window glass due to the temperature difference between the indoor and outdoor.

The window system which is installed in the building and distinguishes the indoor space from the outside generally includes a window frame frame fixed to the structure, a window frame frame installed on the window frame frame by a fixing means, and a window glass fixedly mounted to the window frame.

Due to the large temperature and humidity difference between the indoor space and the winter season, condensation and frost are generated on the corresponding surface of the window glass. These condensation and castles created on the surface of the window glass obscure the view of people living in the room, and also the condensation water flows into the room through the window frame and the window frame and is not sanitary.

In order to solve this problem, the window glass is composed of an indoor glass and an outdoor glass that maintain a predetermined interval, and an inert gas such as argon gas or krypton (Kr) gas in a sealed space between the indoor glass and the outdoor glass. Multi-layer glass windows having a structure to fill the space have been proposed.

In a multilayer glass window having such a structure, when damage occurs to the sealing structure, an inert gas filled in the sealing space between the indoor glass and the outdoor glass leaks, and condensation may occur on the interior glass surface.

As a window having another structure for preventing the occurrence of condensation, a heating wire is provided on the outer side of the interior glass, and has a structure in which an external power source is applied to the heating wire.

However, in the window of such a structure, the whole surface of indoor glass cannot be heated uniformly, and it cannot fully suppress the generation | occurrence | production of condensation. In particular, the glass may be deformed or broken due to the temperature difference between the outer portion and the center portion of the indoor glass.

On the other hand, when such a structure is applied to a large window glass, heat is not transferred to the entire surface of the indoor glass, and thus it is impossible to expect a full condensation prevention effect.

As the window structure known in the art, a window is disclosed in which heat generated from a surface heater is not directly heated on the glass, but the glass is disposed and heated with an air layer having a predetermined width d therebetween. In the windows of such a structure, a glass is heated using radiant heat.

It is an object of the present invention to provide a window system that can effectively suppress condensation occurring on the interior surface of a window glass due to a difference between an indoor temperature and an outdoor temperature.

Window system according to the present invention for realizing the above object is a window frame frame equipped with a power applying means therein; A window frame, which is installed in a window frame frame so as to be movable or fixed, and which is provided with a power supply means electrically connected to the power applying means of the window frame frame; And a window glass provided on the window frame, wherein the heat generating means connected to the power applying means of the window frame is installed over the entire surface.

The window frame constituting the window system comprising a window according to the present invention is fixed to the window frame frame, the fixed window frame frame is installed window glass; And a floating window frame which is movable along the window frame frame and provided with window glass.

Here, the fixed window frame and the floating window frame are each provided with a power supply means electrically connected to the power supply means of the window frame frame, the window glass provided on the fixed window frame and the window glass provided on the floating window frame, the surface resistor on the surface Transparent heat generating layers are formed, respectively.

In addition, the power supply means of the window frame frame includes a wire that can be connected to the external power source and the first connector mounted on the upper surface of the window frame frame and connected to the wire, the power supply means of the window frame frame and the first connector of the window frame frame And a second connector electrically connected.

In particular, the window glass includes an outdoor glass and an indoor glass, and the indoor glass includes a first unit glass corresponding to the outdoor and a second unit glass corresponding to the indoor, wherein the second unit glass and the first unit glass Is integrated with the transparent heating layer formed on the entire surface of any one of the first and second unit glasses therebetween, and the transparent heating layer is electrically connected to the second connector of the window frame.

On the other hand, the second connector provided in the floating window frame is installed on the bottom end of the outer end of the horizontal frame of the window frame, and the corresponding first connector installed in the window frame frame is installed on the upper end surface of the outer end of the horizontal frame so that the floating window frame is completely It is preferable that the first connector and the second connector are electrically connected only in the closed state.

In addition, the indoor glass and the outdoor glass of each window glass installed in the window frame maintain a predetermined interval by the spacer, the space between the indoor glass and the outdoor glass is filled with an inert gas, At the end, an electrode for electrically connecting the wire connected to the second connector and the transparent heating layer is formed.

The window system according to the present invention as described above can effectively prevent the generation of frost and condensation water on the entire surface of the window glass by forming a heat generating means made of a surface resistor on the entire surface of the window glass.

Therefore, in the present invention, the glass is directly heated by flowing electricity by coating a conductive conductive material having a transparency of 80% or more on the glass surface, thus preventing frost and condensation while watching the external scenery in winter.

In addition, when the flow window frame is opened, it is possible to minimize the consumption of energy by cutting off the power applied to the heating means.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of a window system according to the present invention. For convenience, an edge portion of the window frame frame 100 is enlarged at a lower left portion of FIG. 1.

Window system according to the invention is fixed to the window frame frame 100 fixed to the building (not shown), the window frame frame 210, 220 installed on the window frame frame 100 and the window frame frame (210, 220) Window glasses 310, 320.

2 is a cross-sectional view taken along the line “AA” of FIG. 1. In FIGS. 1 and 2, as an example of the window frame, the window frame on the right side is fixed to the window frame frame 100. At 220, the left window frame is illustrated as a floating window frame 210 that can move left and right along the window frame frame 100.

In addition, in the window system shown in FIGS. 1 and 2, the window glasses 310 and 320 installed in the floating window frame 210 and the fixed window frame 220 of the window frame are provided with the indoor glass 311 and 321. It is a figure which shows the double window system which consists of side glass 312,322.

However, the double window system shown in Figs. 1 and 2 is only one embodiment for explaining the present invention, but does not limit the present invention.

The window frame frame 100 constituting the window system according to the present invention is provided with a power applying means therein.

The power applying means of the window frame frame 100 is mounted to the wire 101 and the upper surface of the window frame frame 100 that can be connected to the external power supply (for example, via the plug P) and the wire 101 and And connected first connectors 101-1 and 101-2. Here, two first connectors 101-1 and 101-2 correspond to a predetermined position of the window frame frame 100, that is, the bottom surface of the floating window frame 210 and the bottom surface of the fixed window frame 220. It is installed in each part.

The fixed window frame frame 220 installed in the window frame frame 100 in a fixed state with the floating window frame frame 210 installed to be movable in the window frame frame 100 is a power supply means of the window frame frame 100, that is, the first connector ( 101-1 and 101-2 are respectively provided with power supply means electrically connected.

Here, the power supply means installed in each of the window frames 210 and 220 is a second connector 211 and 221 electrically connected to the first connectors 101-1 and 101-2 of the window frame frame 100, respectively.

Meanwhile, the fixed window frame frame 220 illustrated in FIGS. 1 and 2 is installed in the window frame frame 100 in a fixed state. Therefore, the second connector 221 installed on the fixed window frame 220 and the first connector 101-2 of the window frame frame 100 corresponding thereto are always in contact with each other, thereby limiting the installation position thereof. There is no.

However, as shown in part “C” of FIG. 1, in the floating window frame 210 moving left and right on the window frame frame 100, the second connector 211 has an outer end (vertical) of the horizontal frame 210-1. On the bottom of the edge adjacent to the frame 210-2, and on the window frame frame 100, a first connector 101-1 is adjacent to the outer end (the vertical frame 110-2) of the horizontal frame 110-1. Corner portion) is preferably installed on the upper surface (here, Figure 2 shows the second connector 211 installed in the flow window frame 210 for convenience).

Therefore, in the open state according to the movement of the floating window frame 210, the electrical connection between the second connector 211 installed in the floating window frame 210 and the first connector 101-1 installed in the window frame frame 100 is performed. The relationship is released. That is, electricity is supplied to the second connector 211 of the flow window frame 210 only when the flow window frame 210 is closed.

Meanwhile, the position of the second connector 211 in the floating window frame 210 and the position of the first connector 101-1 in the window frame frame 100 corresponding thereto are not limited. For example, by installing the first connector on the surface of the vertical frame (110-2) of the window frame frame 100, and positioning the second connector on the surface of the vertical frame (210-2) of the floating window frame 210 When the floating window frame 210 moves, that is, at the moment when the floating window frame 210 is opened, the electrical connection state of both connectors may be released.

The window glasses 310 and 320 respectively mounted to the floating window frame 210 and the fixed window frame 220 are electrically connected to the power supply means of the window frames 210 and 220, that is, the second connectors 211 and 221, respectively. Heating means connected by means of installation is installed.

The window glass 310 and 320 mounted to the floating window frame 210 and the fixed window frame frame 220 and the heat generating means provided to each window glass 310 and 320 have the same structure and function. In the description, heat generating means provided in the window glass 310 of the floating window frame 210 will be described as an example.

As described above, the window glass 310 of the floating window frame 210 includes an indoor glass 311 and an outdoor glass 312 disposed at predetermined intervals by the spacer S-1. An edge portion of the interior glass 311 and the exterior glass 312 is attached to a sealing member to be described later, and thus a sealing space completely isolated from the outside is formed between the interior glass 311 and the exterior glass 312. .

On the other hand, the interior glass 311 is the outer unit glass 311-1 corresponding to the interior space, the outer unit glass 311-2 corresponding to the sealing space (S) and the outside of the inner unit glass 311-1. The transparent heating layer 311-3 formed on the surface (or the inner surface of the outer unit glass 311-2).

The transparent heating layer 311-3 is formed of a material having excellent electrical conductivity and heat generating properties, such as carbon nanotubes, ITO, ZnO, SnO _2, and a surfactant or a transparent resin for evenly dispersing them. It is a surface resistor formed of a material. The transparent heat generating layer 311-3 is formed over the outer surface of the inner unit glass 311-1 (or the entire surface of the inner surface of the outer unit glass 311-2), and the transparent heating layer 311-3. 3) is electrically connected to the second connector 211 installed in the flow window frame 210 through the conductive wire 201.

By such a structure, the heat generating means, ie, the transparent heat generating layer 311-3, installed on the interior glass 311 of the window glass 310 of the floating window frame 210 is connected to the wire 201, the fixed window frame ( It may be electrically connected to an external power source through the second connector 211 installed at 210, the first connector 101-1 installed at the window frame frame 100, and the wire 101.

FIG. 3 is a partial detailed view of part “B” of FIG. 2, detailing the structures of the window glass 310 provided in the flow window frame 210 and the transparent heating layer 311-3 provided in the window glass 310 in detail. For convenience, the floating window frame supporting the window glass 310 is not shown.

As described above, the indoor glass 311 and the outdoor glass 312 of the window glass 310 installed in the flow window frame (not shown in FIG. 3) are spaced at a predetermined interval by the spacer S-1. While maintaining, the space S between the indoor glass 311 and the outdoor glass 312 is filled with an inert gas.

In order to prevent the leakage of the inert gas, the boundary between the interior glass 311 and the flow window frame 210 (FIG. 2) and the boundary between the outdoor glass 312 and the flow window frame 210 210 is organic based. It is preferable to seal with a sealing material.

On the other hand, the electrode for applying power to the transparent heating layer 311-3 formed on the outer surface (or the inner surface of the outer unit glass 311-2) of the inner unit glass 311-1 of the interior side glass 311 (311-3A) is formed. The electrode 311-3A is made of a conductive paste, and is electrically connected to a second connector 211 of FIG. 2 installed through the wire 201 in the flow window frame 210 of FIG. 2. Here, it is preferable to surround the electrode 311-3A with the insulating tape T to insulate the electrode 311-3A connected to the wire 201.

The function of the window system according to the present invention configured as described above will be described with reference to the drawings.

When the temperature difference between the indoor space and the outdoor is large, such as in winter, and when the floating window frame 210 is closed, the window glasses 310 and 320 installed in the floating window frame 210 and the fixed window frame 220, respectively, As shown in FIGS. 1 and 2, that is, the interior glass of the double window is composed of the interior glass 311 and 321 and the exterior glass 312 and 322. Condensation water is generated on the indoor corresponding surfaces of 311 and 321.

In this condition, when power is applied to the wire 101 which is a power applying means of the window frame frame 100, the power is supplied to the first connectors 101-1 and 101-2 installed on the window frame frame 100 through the wire 101. After that, the power is transferred to the second connectors 211 and 221 of the window frames 210 and 220 electrically connected to the first connectors 101-1 and 101-2.

The power delivered to the second connectors 211 and 221 is the glass 311 inside the window glass 310 and 320 through the wires 201 and 202 and the electrodes electrically connected thereto (311-3A of FIG. 3). 321 is applied to the transparent heat generating layers 311-3 and 321-3. Therefore, the dew condensation water generated on the indoor corresponding surfaces of the interior glasses 311 and 321 of the window glasses 310 and 320 is evaporated and removed by the heat generated in the transparent heating layers 311-3 and 321-3.

On the other hand, the main material of the transparent heating layer (311-3, 321-3) that generates heat by the application of power is made of a transparent resin, the user in the room can see the outside through each window glass (310, 320) The transparent heating layers 311-3 and 321-3 do not affect the functions of the window glasses 310 and 320.

If the moving window frame frame 210 is moved and opened for indoor ventilation, the second connector 211 installed on the floating window frame 210 and the first connector 101-1 installed on the window frame frame 100 are electrically connected to each other. The connection state is released, and thus, the power supply is cut off, so that no heat generation occurs in the transparent heating layer 311-3 formed in the glass 311 inside the window glass 310.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art having various ordinary knowledge of the present invention may make various modifications, changes, and additions within the spirit and scope of the present invention. And additions should be considered to be within the scope of the following claims.

For example, the window system according to the present invention is installed on the control unit 400 installed in the window frame frame 100, the indoor corresponding surface of each window glass (310, 320) to transmit a signal about the temperature of the room to the control unit 400 Power installed between the temperature sensor (not shown) to transmit and the first connectors (101-1, 101-2) of the window frame frame 100 and an external power source to block the flow of power under the control of the controller 400 The blocking unit 500 may further include.

Power may be supplied to the transparent heating layers 311-3 and 321-3 only when the corresponding surfaces of the window glasses 310 and 320 reach a temperature lower than the set temperature by the members.

In addition, when an external shock is applied to or damaged on the window glasses 310 and 320, and when the power supply is not normally performed due to an abnormality of the member (for example, a poor connection of the connector or a short circuit of the wire), The power cutoff unit 500 may cut off the power supply.

In addition, the shapes of the first connector and the second connector that are electrically connected are not limited. However, as shown in FIG. 2, the second connector 211 provided on the floating window frame 210 moving on the window frame frame 100 has one or more recesses corresponding thereto. The first connector 101-1 forms one or more convex portions accommodated in the recesses of the second connector 211 so that both connectors 101-1 and 211 are moved even after the flow window frame 210 is moved. Can be precisely electrically connected.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic perspective view of a window system according to the present invention, showing a double window system comprising a fixed window frame and a floating window frame mounted on a window frame.

FIG. 2 is a cross-sectional view taken along the line “AA” of FIG. 1, illustrating a double window system in which a fixed window frame of a window frame and a window glass installed in a floating window frame are formed of an outdoor glass and an indoor glass; FIG. .

FIG. 3 is a detailed perspective view of the portion “B” of FIG. 1.

Claims (8)

A window frame frame equipped with a power applying means therein; A window frame, which is installed in a window frame frame so as to be movable or fixed, and which is provided with a power supply means electrically connected to the power applying means of the window frame frame; And A window system comprising a window glass provided on the window frame and having heat generating means connected to the power applying means of the window frame over the entire surface. The method of claim 1, wherein the window frame, A fixed window frame frame fixed to the window frame and provided with window glass; And Moveable along the window frame, including a floating window frame with window glass, The fixed window frame and the floating window frame are each provided with a power supply means electrically connected to the power applying means of the window frame frame, A window system according to claim 1, wherein the window glass installed in the fixed window frame and the window glass provided in the floating window frame are each formed with a transparent heating layer made of a surface resistor. The window system according to claim 2, wherein the transparent heating layer is made of a mixture of carbon nanotubes and a transparent resin. The method according to claim 1 or 2, The power applying means of the window frame frame includes a wire that can be connected to an external power source and a first connector mounted to the upper surface of the window frame frame and connected to the wire, The power supply means of the window frame comprises a second connector electrically connected with the first connector of the window frame, The window glass includes an outdoor glass and an indoor glass, and the indoor glass includes a first unit glass corresponding to the outside and a second unit glass corresponding to the interior, wherein the second unit glass and the first unit glass are made of first glass. An integrated window system comprising a transparent heating layer formed on the entire surface of any one of the first and second unit glasses, the transparent heating layer being electrically connected to the second connector of the window frame. . 5. The method of claim 4, wherein the second connector provided on the floating window frame is installed on the bottom end surface of the horizontal frame of the window frame, and the corresponding first connector provided on the window frame frame is installed on the outer end top surface of the horizontal frame. A window system according to claim 1, wherein the first connector and the second connector are electrically connected only when the window frame is completely closed. The glass of claim 4, wherein the indoor glass and the outdoor glass of each window glass installed in the window frame are kept at a predetermined interval by a spacer, and the space between the indoor glass and the outdoor glass is filled with an inert gas. A window system according to claim 2, wherein an electrode for electrically connecting the wire connected to the second connector and the transparent heating layer is formed at the end of the side glass. The method of claim 6, wherein the boundary between the end of the indoor glass and the outdoor glass of the window glass and the window frame is sealed with an organic material, and the connection between the electrode and the wire is finished with insulating tape. Window system. The method of claim 1, A control unit installed in the window frame frame; A sensor installed on an indoor corresponding surface of the window glass to transmit a signal relating to the indoor temperature to the controller; And And a power cut-off unit disposed on the window frame frame, the power cut-off unit being disposed between the power applying means and the external power supply to block the flow of power to the power applying means under the control of the controller.

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