KR102025278B1 - Insulation system for double windows - Google Patents

Abstract

The present invention relates to a double glazing insulation system. The double glazing insulation system according to the present invention includes a chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, and the plurality of beads and air received in the chamber are discharged. A double pane forming a bead outlet and at least one air inlet and outlet for air to and from the chamber; A movable body provided to be movable in the chamber while maintaining a gap between the pair of glass windows; And a moving unit moving unit for moving the moving unit.

Description

Double Window Insulation System {INSULATION SYSTEM FOR DOUBLE WINDOWS}

The present invention fills a plurality of beads in a chamber between a pair of glass windows to insulate, awn and sound insulation between a pair of glass windows, or discharge a plurality of beads contained in a chamber to view a window between a pair of glass windows. More particularly, the present invention relates to a double glazing insulation system capable of preventing shrinkage of the double glazing due to air flow in the chamber.

In buildings, glass windows isolate the natural and indoor environments, act as a supply path for sunlight and fresh outside air, and are essential components that make people feel vista and open.

In recent years, the size of windows and doors tends to increase in order to enhance the appearance of buildings.

Therefore, it is important to minimize heat loss through the window to reduce the energy used in the building.

In order to solve these problems, conventionally, gas enclosed double panes for injecting gas having low thermal conductivity into a chamber, such as a vacuum glazing, low-emission coated glass, transmittance control glass, multilayer glass, etc. have been developed. As it requires a special manufacturing technology, the price is increased, it is difficult to use universally.

In addition, even if a thermal insulation effect is obtained by various conventional double windows, there is a problem in that additional curtains or blinds must be additionally installed to prevent invasion of solar radiation.

In order to solve this problem, the plurality of beads are filled in the chamber between the pair of glass windows by the blowing of the blower to insulate, shade and sound insulation between the pair of glass, or discharge the plurality of beads filled in the chamber. Thus, a double glazing insulation system is being developed which allows viewing between a pair of glass.

By the way, in the double-window insulation system using a plurality of beads, when the plurality of beads contained in the chamber between the pair of glass windows by the blower blows into the storage tank, or filling the plurality of beads stored in the storage tank to the chamber, Negative pressure is generated in the chamber, and the central area of the chamber shrinks, causing the window to break.

In addition, the double-window insulation system using a plurality of beads, as the beads flow between the chamber and the reservoir, the static electricity is generated between the beads and the beads agglomerate, the beads flow smoothly in the chamber or reservoir, stagnated and bottlenecked It causes a phenomenon, in particular, the beads remaining in the chamber is increased to keep the glass window clean, reducing the user's convenience, power consumption of the blower is also increased, there is a problem that lowers the performance of the entire system.

Korean Unexamined Patent Publication No. 10-2003-0013032 (Invention name: Window insulation system of double-window structure using beads, Publication date: February 14, 2003) US Patent No. 9,151,105 (Invention name: WINDOW INSULATION SYSTEM AND METHOD OF OPERATING THE SAME, Registered Date: 2015.10.06.) Japanese Patent Application Laid-Open No. 7-189561 (Invention: Insulation Window, Publication Date: July 28, 1995)

The present invention is to solve the above problems, it is an object of the present invention to provide a double-window insulation system that can prevent the chamber of the double-window shrinkage to reduce the breakage of the glass window.

In addition, the present invention, when the bead contained in the chamber of the double glazing, the bead contained in the chamber can be quickly discharged without stagnation, to reduce the bead remaining in the chamber, to keep the glass window clean user convenience It is another object to provide a double glazing insulation system that improves.

An object of the present invention is a chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, a bead outlet through which the plurality of beads and air received in the chamber are discharged; A double glazing forming one or more air inlets and outlets through which air enters the chamber; A movable body provided to be movable in the chamber while maintaining a gap between the pair of glass windows; And a moving unit moving unit for moving the moving unit.

Here, the movable body is provided to be elevated in the chamber, the movable body moving unit, the suspension supporting the movable body, the wire for lifting the movable body; A wire drum in which the wire is wound or unwound; And it may include a drive motor for a wire drum for rotating the wire drum.

The movable body is provided in a plurality of movable in the chamber, the movable body moving unit, In another embodiment, the suspension support for the plurality of the movable body, and lifting the plurality of movable bodies; One or more auxiliary wires connecting the plurality of moving bodies to be spaced apart from each other; A wire drum in which the wire is wound or unwound; And it may include a drive motor for a wire drum for rotating the wire drum.

The movable body is provided to be accessible or spaced apart from the bead inlet, and the movable body moving unit, as another embodiment, is provided transverse to the movable body, the screw shaft for the movable body screwed with the movable body; And a screw shaft drive motor for moving the screw shaft for the movable body.

The movable body may be provided in plural number so as to be accessible or spaced apart from the inlet of the bead, and the movable body moving unit may further include one or more auxiliary wires connecting the plurality of movable bodies to be spaced apart from each other; A screw shaft for a movable body provided horizontally with respect to the movable body and screwed to any one of the movable bodies; And a screw shaft drive motor for moving the screw shaft for the movable body.

The movable body is provided to be accessible or spaced apart from the bead inlet, and the movable body moving unit, in another embodiment, a drive rod connected to the movable body; And an actuator configured to linearly reciprocate the moving body by lengthening and reducing the driving rod.

It may further include a guide provided along the moving direction of the movable body, to guide the movement of the movable body.

It may further include bead discharge means for discharging the plurality of beads contained in the chamber to the bead outlet.

The bead discharge means, the chamber air inlet pipe is provided to communicate with the chamber on the opposite side of the bead discharge port for introducing air into the chamber; And a valve for the chamber air inlet tube provided in the chamber air inlet tube to open and close the chamber air inlet tube.

In another embodiment, the bead discharge means may be formed by stacking a plurality of pipes having different lengths and provided at the bottom of the chamber or the chamber air inlet pipe to supply air flowing along the chamber air inlet pipe to the bead outlet port. It may further include an air injection member for spraying toward.

The bead discharge means, as another embodiment, the screw shaft having a spiral shape, rotatably provided at the bottom of the chamber toward the bead outlet; And a screw shaft drive motor for rotating the screw shaft.

The bead discharging means may further include a belt conveyor provided at the bottom of the chamber to form a caterpillar and discharging the plurality of beads contained in the chamber toward the bead outlet.

A reservoir for storing the plurality of beads; And a main blower to suck or blow air into the chamber to fill the chamber with the plurality of beads stored in the reservoir or to discharge the plurality of beads filled in the chamber into the reservoir. have.

A bead flow tube connected to the reservoir to guide the plurality of beads to flow; A bead supply pipe branched from the bead flow pipe and connected to the bead inlet; A bead discharge pipe branched from the bead flow pipe and connected to the bead discharge port; An air discharge pipe connected to the reservoir for guiding the flow of air discharged from the reservoir; An air flow pipe connected to the air inlet and guiding a flow of air to and from the air inlet; And a communication tube communicating with the air flow tube and the air discharge tube and provided with the main blower.

A branch pipe branched from the air flow pipe to guide the flow of air; A branch pipe valve provided in the branch pipe to open and close the branch pipe; And an auxiliary blower provided in the branch pipe and configured to press-fit and blow air into the chamber through the branch pipe and the air flow pipe.

The chamber air inlet pipe may branch from the air flow pipe or the branch pipe.

A bead flow pipe valve provided in the bead flow pipe to open and close the bead flow pipe; A bead supply pipe valve provided in the bead supply pipe to open and close the bead supply pipe; A bead discharge pipe valve provided in the bead discharge pipe to open and close the bead discharge pipe; An air discharge pipe valve provided in the air discharge pipe to open and close the air discharge pipe; And an air flow valve provided in the air flow pipe to open and close the air flow pipe, wherein the bead flow pipe valve and the bead supply pipe valve are opened when the plurality of beads are filled in the chamber from the reservoir. The bead discharge pipe valve is closed, the bead flow pipe valve and the bead discharge pipe valve is open and the bead supply pipe valve can be closed when the plurality of beads are discharged from the chamber to the reservoir.

A bead recovery pipe branched from the bead supply pipe or the bead flow pipe and connected to the reservoir; And a bead recovery tube valve provided in the bead recovery tube to open and close the bead recovery tube, wherein the bead recovery tube valve is closed when the plurality of beads are filled in the chamber from the reservoir, When the beads are discharged from the chamber into the reservoir, the valve for the bead return pipe may be opened.

In another embodiment, an object of the present invention is to provide a chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, and the plurality of beads and air received in the chamber. A double pane forming a bead outlet to be discharged and at least one air outlet through which air enters and exits the chamber; And one or more supports provided in the chamber, the one or more supports being fixed to and supported by the pair of glass windows to maintain a distance between the pair of glass windows.

According to the present invention, it is possible to prevent the chamber of the double glazing to shrink and reduce breakage of the glazing. In addition, when the beads contained in the chamber of the double window is discharged, the beads contained in the chamber can be discharged quickly without stagnation, can reduce the beads remaining in the chamber, can keep the glass window clean, thereby improving user convenience. .

1 is a block diagram of a double glazing insulation system according to a first embodiment of the present invention,
2 is a view illustrating a process in which a plurality of beads are filled in the double window of the double window insulation system of FIG.
3 is a view illustrating a process of discharging a plurality of beads from the double glazing of the double glazing insulation system of FIG.
4 is an enlarged view of a main portion for showing the operation of the bead discharge means of FIG.
5 is a configuration diagram showing another embodiment of the bead discharge means;
6 is a perspective view of the air injection member of FIG.
7 is a configuration diagram showing another embodiment of the bead discharge means;
8 is a configuration diagram showing another embodiment of the bead discharge means;
9 is a configuration diagram of a double glazing insulation system according to a second embodiment of the present invention,
10 and 11 are views illustrating a process of filling a plurality of beads in the double glazing of the double glazing insulation system of FIG.
12 to 14 are views illustrating a process of discharging a plurality of beads from the double glazing of the double glazing insulation system of FIG.
15 is a block diagram of a double glazing insulation system according to a third embodiment of the present invention,
16 and 17 are views illustrating a process in which a plurality of beads are filled in the double glazing of the double glazing insulation system of FIG.
18 and 19 are views illustrating a process of discharging a plurality of beads from the double glazing of the double glazing insulation system of Figure 15,
20 is a plan view illustrating a state in which the movable body of FIG. 15 is accommodated in a chamber;
FIG. 21 is a plan view illustrating a state in which a moving body is accommodated in a chamber during filling and discharging of the bead of FIG. 15;
22 is a block diagram of a double glazing insulation system according to a fourth embodiment of the present invention,
23 is a fifth embodiment of the present invention, in which the internal structure of the double window of the double window insulation system according to the first embodiment of the present invention is modified.
24 is a view illustrating an operating state of the movable body of FIG. 23;
25 is a sixth embodiment of the present invention, in which the internal structure of the double window of the double window insulation system according to the second embodiment of the present invention is modified.
FIG. 26 is a view illustrating an operating state of the movable body of FIG. 25;
27 is a perspective view of the movable body.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be embodied in various different forms, and the present embodiments only make the disclosure of the present invention complete, and those of ordinary skill in the art to which the present invention belongs. It is provided to fully inform the skilled person the scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, "comprises" and / or "comprising" does not exclude the presence or addition of one or more other components in addition to the mentioned components. Like reference numerals refer to like elements throughout, and "and / or" includes each and all combinations of one or more of the mentioned components. Although "first", "second", etc. are used to describe various components, these components are of course not limited by these terms. These terms are only used to distinguish one component from another. Therefore, of course, the first component mentioned below may be a second component within the technical spirit of the present invention.

Unless otherwise defined, all terms used in the present specification (including technical and scientific terms) may be used in a sense that can be commonly understood by those skilled in the art. In addition, terms that are defined in a commonly used dictionary are not ideally or excessively interpreted unless they are specifically defined clearly.

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

Prior to the description, it will be described below that the double glazing insulation system is applied to one double glazing, but the technical spirit of the present invention is known in advance that can be applied to a plurality of double glazing.

In addition, in the various embodiments, components having the same configuration will be described in the first embodiment by using the same reference numerals, and in other embodiments, only the configuration different from the first embodiment will be described.

1 to 3 show a double glazing insulation system according to a first embodiment of the present invention.

As shown in these drawings, the double glazing insulation system according to the first embodiment of the present invention includes a double glazing 10, a moving body 160, and a moving body moving unit 170a.

Double window 10 has a structure in which a pair of glass windows are arranged side by side at a predetermined interval, supported by a window frame frame (not shown).

An internal space is formed between the pair of glass windows, for example, the chamber 11 is formed. The chamber 11 has a filled state in which a plurality of beads 1 are filled, or a discharged state in which the plurality of beads 1 are not received. When the plurality of beads (1) is filled in the chamber 11, the double glazing 10 is insulated, shaded and soundproof, and when the plurality of beads (1) is discharged from the chamber 11 through the double glazing 10 You will be able to see.

Here, the plurality of beads 1 will be briefly described, and filled with air and gas inside so as to have heat insulation with spherical grains. Although the bead 1 is preferably made of a foamed styrofoam material having excellent fluidity by blowing, the material of the bead 1 is not limited thereto, and other types of foamed foams and hydrogels may be used. In addition, the color of the beads 1 preferably has a white color for blocking sunlight or a transparent color for transmitting sunlight. In summer, white beads (1) can be used to block the sun's heat and heat insulation. In winter, white or transparent beads (1) can be used to provide a so-called, thinning effect. It can be seen, and the thermal insulation effect can be obtained. On the other hand, the color of the bead 1 is not limited, and may be manufactured in various colors. In addition to the spherical shape, the bead 1 may have various cross-sectional shapes, such as an ellipse and a polygon.

On the other hand, the double window 10 forms a chamber 11 and is sealed by the window frame frame.

For example, a plurality of beads 1 and a bead inlet 13 through which air is introduced into the chamber 11 may be formed at an upper end of one side of the double window 10.

An air inlet 15 through which air enters and exits the chamber 11 is formed at the upper left side of the double window 10.

The bead blocking member 17 for the chamber is provided inside the chamber 11 adjacent to the air inlet 15 along the vertical direction of the double window 10. The bead blocking member 17 for the chamber has a rectangular plate shape and is coupled to the air inlet 15 of the double glazing 10. A plurality of air passage holes (not shown) having a semi-circular cross-sectional shape smaller than the diameter of the bead 1 are formed at both edges of the chamber bead blocking member 17 in close contact with each glass window surface of the double window 10. have. Thus, the bead blocking member 17 for the chamber allows only the air to enter and exit the chamber 11 through the air passage hole, thereby preventing the bead 1 from entering the air flow pipe 91 to be described later. Here, the air through hole is described as having a semi-circular cross-sectional shape, but is not limited thereto, and the air through hole may be formed in one or more slots along the length direction of the bead blocking member 17 for the chamber. In addition, the bead blocking member 17 for the chamber may be formed in a mesh shape in which a plurality of through holes having a diameter smaller than the diameter of the bead 1 is formed.

Meanwhile, a plurality of beads 1 accommodated in the chamber 11 and a bead discharge port 19 through which air is discharged are formed at one side of the window frame frame between the double windows 10.

In addition, the double window 10 is provided with a pressure measuring sensor 21 for measuring the pressure in the chamber 11 and a distance measuring sensor 23 for measuring the bead filling distance in the chamber 11. Here, an ultrasonic sensor may be provided as the distance measuring sensor 23.

And the movable body accommodating part 27 in which the movable body 160 is accommodated is provided in the center of the upper end of the double window 10.

The movable body 160 is formed of a pentagonal cross-sectional block, and is provided to be movable in the chamber 11 so as to move up and down in the chamber 11 while maintaining a gap between the pair of glass windows. The movable body 160 moves up and down along the center axis of the chamber 11. The movable body 160 has a thickness corresponding to the distance between the pair of glass windows. Here, in the present embodiment, although the moving body 160 is illustrated as having a pentagonal cross-sectional shape, the present invention is not limited thereto, and the moving body 160 may have a polygonal cross-sectional shape such as a triangle and a quadrangle.

The movable body moving unit 170a moves the movable body 160 accommodated in the chamber 11. The moving unit 170a includes a wire 171, a wire drum 173, and a drive motor 175 for a wire drum.

The wire 171 suspends and supports the movable body 160 and elevates the movable body 160.

The wire drum 173 has a cylindrical shape and is provided on the outer upper portion of the double glazing 10 to wind and unwind the wire 171.

The drive motor 175 for the wire drum is provided on the outer upper portion of the double window 10 to rotate the wire drum 173 forward and backward.

As a result, when the drive motor 175 for the wire drum is rotated in one direction, the wire 171 is wound around the wire drum 173 and the movable body 160 is raised above the chamber 11. In addition, when the drive motor 175 for the wire drum is rotated in the other direction, the moving body 160 is lowered to the bottom of the chamber 11 while the wire 171 is unwound from the wire drum 173.

On the other hand, the double glazing insulation system according to the first embodiment of the present invention further comprises a bead discharge means (30a) for discharging the plurality of beads (1) accommodated in the chamber (11) to the bead outlet (19). The bead discharge means 30a is provided on the other side of the window frame frame bottom between the double windows 10, for example, on the side opposite to the bead discharge port 19. In this embodiment, as the bead discharge means 30a, the chamber air inlet pipe 31 and the valve 33 for the chamber air inlet pipe are provided.

The chamber air inlet tube 31 has a hollow pipe or duct shape. The chamber air inlet pipe 31 communicates with the chamber 11 and serves to guide the flow of air so that external air flows into the chamber 11 filled with the beads 1. The chamber air inlet tube 31 is located on the side opposite to the bead outlet 19 with the chamber 11 interposed therebetween. In this embodiment, the chamber air inlet pipe 31 is shown as being connected to the branch pipe 101 via the air flow pipe 91, but is not limited to this, the chamber air inlet pipe 31 is connected to the branch pipe 101 It may be directly connected, or may be connected to an auxiliary air flow pipe 111 to be described later, or may be connected to a separate blower, or used independently.

The chamber air inlet pipe 31 is provided with a chamber air inlet pipe valve 33 for opening and closing the chamber air inlet pipe 31. By the opening and closing operation of the valve 33 for the chamber air inlet pipe, it is possible to control the flow of air introduced into the chamber 11 along the chamber air inlet pipe 31.

As such, when discharging the plurality of beads 1 filled in the chamber 11 of the double glazing 10 to the reservoir 50, residual beads generated in the bottom region opposite to the bead discharge port 19 of the chamber 11. (1), the outside air flowing through the chamber air inlet pipe 31 is supplied toward the bead outlet 19 in the bottom region of the chamber 11, whereby a plurality of beads (1) filled in the chamber 11 is When discharged through the bead outlet 19, the bead 1 is inclined to the bottom region of the opposite side of the bead outlet 19 of the chamber 11, without stagnation, and smoothly into the reservoir 50 through the bead outlet 19. Is discharged. This makes it possible to eliminate the beads 1 remaining in the bottom region of the chamber 11.

On the other hand, the bottom of the chamber 11, as another embodiment of the bead discharge means 30b, as shown in Figures 5 and 6, the air flowing along the chamber air inlet pipe 31, the bead outlet 19 An air injection member 35 for spraying toward may be further provided.

As shown in FIG. 6, the air injection member 35 has a structure in which a plurality of pipes having different lengths are stacked. For example, the air injecting member 35 has different lengths and arranges long pipes closer to the bottom of the chamber 11, and stacks short pipes having different lengths and shorter distances from the chamber 11. It is formed into a laminate. In addition, a plurality of air injection holes 37 penetrate through the surface of the air injection member 35.

As a result, the outside air introduced into the chamber air inlet tube 31 passes through a plurality of pipes having different lengths, increases the flow rate, and at the same time, the bead outlet 19 of the chamber 11 at different positions of the chamber 11. By spraying toward, the plurality of beads 1 filled in the chamber 11 do not remain in the bottom region of the chamber 11 by the laminar flow generated by the air injected from the air injecting member 35. It is discharged to the reservoir 50 through the bead outlet (19). In particular, the plurality of beads 1 stay in the bottom of the chamber 11 by the air injected toward the bottom of the air chamber 11 through the plurality of air injection holes 37 formed in the air injecting member 35. And it can be smoothly discharged toward the bead outlet 19.

7 shows another embodiment of the bead discharging means 30c. As shown, the bead discharging means 30c includes a screw shaft 41 and a screw shaft drive motor 43, unlike the bead discharging means 30a, 30b described above.

The screw shaft 41 has a spiral shape and is rotatably provided at the bottom of the chamber 11 toward the bead outlet 19.

The screw shaft drive motor 43 is provided on the outside of the double window 10 to rotate the screw shaft 41.

As a result, when the screw shaft drive motor 43 is operated, the screw shaft 41 rotates while performing a helical motion, and a predetermined amount of the beads 1 located in the bottom region on the opposite side of the bead outlet port 19 of the chamber 11 is obtained. It is transported toward the bead outlet 19 each. Therefore, the beads 1 remaining in the chamber 11 are not inclinedly stacked on the bottom region of the chamber 11, and are smoothly discharged to the reservoir 50 through the bead outlet 19, and the bottom of the chamber 11 is disposed. It is possible to eliminate the bead 1 remaining in the region.

Here, in the present embodiment, as the bead discharge means, it is shown that the chamber air inlet pipe 31, the chamber air inlet pipe valve 33, the screw shaft 41, and the screw shaft drive motor 43 are provided together. It is not limited, Only the screw shaft 41 and the screw shaft drive motor 43 may be provided as a bead discharge means.

8 shows another embodiment of the bead discharge means 30d. As shown, the bead discharging means 30d comprises a belt conveyor 45, unlike the bead discharging means 30a, 30b, 30c described above.

The belt conveyor 45 is provided in the bottom region of the chamber 11, and the belt 47 which forms a caterpillar, the roller 49 which rotates the belt 47, and the belt drive which rotates the roller 49 are provided. It includes a motor (not shown).

As such, by providing the belt conveyor 45 in the bottom region of the chamber 11, the beads 1 located in the bottom region on the opposite side of the bead outlet 19 of the chamber 11 are stacked on the belt 47 and the beads are beaded. It is conveyed toward the outlet 19. Therefore, the beads 1 remaining in the chamber 11 are not inclinedly stacked on the bottom region of the chamber 11, and are smoothly discharged to the reservoir 50 through the bead outlet 19, and the bottom of the chamber 11 is disposed. It is possible to eliminate the bead 1 remaining in the region.

Here, in the present embodiment, although the chamber air inlet pipe 31, the chamber air inlet pipe valve 33, and the belt conveyor 45 are shown as being provided together, the present invention is not limited thereto. Only the belt conveyor 45 may be provided.

On the other hand, in the present embodiment, the main blower 97, which will be described later by the bead discharge means 30a, 30b, 30c, 30d, sucks and blows the air in the chamber 11, and stores the plurality of beads 1 stored in the storage tank 50. ) Is described as being applied to the double-window insulation system for filling the chamber 11 or the plurality of beads 1 filled in the chamber 11 to the reservoir 50, but is not limited thereto, and the main blower 97 ) Press-in blows air in the chamber 11 to fill the plurality of beads 1 stored in the reservoir 50 in the chamber 11 or to store the plurality of beads 1 filled in the chamber 11. It can also be applied to double glazing insulation systems that discharge to 50). That is, the above-described bead discharge means (30a, 30b, 30c, 30d), the plurality of beads (1) stored in the reservoir 50 is filled in the chamber 11 or the plurality of beads filled in the chamber 11 When (1) is discharged into the reservoir 50, it can be applied to both the double-window insulation system of the various forms of suction blowing air of the chamber 11, or pressurized blow air to the chamber (11).

On the other hand, the double-window insulation system according to the first embodiment of the present invention is the reservoir 50, the bead flow pipe 71, the bead supply pipe 75, the bead discharge pipe 81, the air discharge pipe 85, air The flow pipe 91, the communication pipe 95, and the main blower 97 are included.

The reservoir 50 has a hollow closed cylindrical shape and stores a plurality of beads 1.

The bead blocking member 51 for the storage tank is provided in the upper inner region of the storage tank 50. The bead blocking member 51 for the storage tank has a mesh shape in which a plurality of through holes (not shown) are formed. The plurality of through holes formed in the bead blocking member 51 for the storage tank have a diameter smaller than the diameter of the bead 1, and the bead blocking member 51 for the storage tank has a plurality of beads 1 introduced into the storage tank 50. Is prevented from leaking to the air discharge pipe (85).

In addition, a reservoir air inlet pipe 53 is connected to the reservoir 50. The reservoir air inlet pipe 53 has a hollow pipe or duct shape. The reservoir air inlet pipe 53 is connected to the side wall of the reservoir 50 between the bead blocking member 51 and the air discharge pipe 85 for the reservoir, so that the outside air into the reservoir 50, more specifically, the reservoir It serves to guide the flow of air to be introduced above the plurality of beads (1) stored in (50).

The reservoir air inlet pipe 53 is provided with a reservoir air inlet pipe valve 55 for opening and closing the reservoir air inlet pipe 53. By the opening and closing operation of the valve 55 for the storage air inlet pipe, it is possible to control the flow of air introduced into the storage tank 50 along the storage air inlet pipe 53.

Accordingly, when the outside air is introduced above the plurality of beads 1 stored in the storage tank 50, when the beads 1 are filled in the chamber 11, the plurality of beads 1 stored in the storage tank 50 are bottlenecked. It is possible to smoothly discharge from the reservoir 50 without developing.

 Here, the reservoir air inlet pipe 53 and the valve 55 for the reservoir air inlet pipe may be selectively provided as necessary.

In addition, the reservoir 50 further includes an agitator 61 for stirring the plurality of beads 1 accommodated in the reservoir 50. The agitator 61 includes an impeller 63 having a plurality of vanes, and a drive motor 65 for the agitator for rotating the impeller 63.

As such, by providing the agitator 61 in the reservoir 50, the plurality of beads 1 stored in the reservoir 50 are mixed evenly, and the beads 1 are agglomerated by static electricity generated between the beads 1. At the same time, the plurality of beads 1 stored in the storage tank 50 can be smoothly discharged from the storage tank 50 without the bottleneck.

In addition, a sight glass (not shown) made of a transparent material may be installed on the outer wall of the storage tank 50 along the height direction of the storage tank 50 to visually check the amount of the beads 1 stored in the storage tank 50.

Meanwhile, the reservoir 50 is connected to the bead outlet 19 of the double glazing 10 by the bead flow tube (71). The bead flow tube 71 has a hollow pipe or duct shape, and serves to guide the plurality of beads 1 to flow.

The bead flow tube 71 is provided with the bead flow tube valve 73 which opens and closes the bead flow tube 71. By opening and closing the bead flow tube valve 73, the flow of the beads 1 flowing along the bead flow tube 71 can be interrupted.

The bead flow pipe 71 is branched into the bead supply pipe 75 and the bead discharge pipe (81).

The bead supply pipe 75 has a hollow pipe or duct shape and is branched from the bead flow pipe 71 and connected to the bead inlet 13. The bead supply pipe 75 serves to guide the plurality of beads 1 discharged from the reservoir 50 to the chamber 11.

The bead supply pipe 75 is provided with the bead supply pipe valve 77 which opens and closes the bead supply pipe 75. By opening and closing the bead supply pipe valve 77, the flow of the beads 1 flowing along the bead supply pipe 75 can be interrupted.

The bead discharge pipe 81 has a hollow pipe or duct shape and is branched from the bead flow pipe 71 and connected to the bead discharge port 19. The bead discharge pipe 81 serves to guide the plurality of beads 1 discharged from the chamber 11 to the reservoir 50.

The bead discharge pipe 81 is provided with the bead discharge pipe valve 83 which opens and closes the bead discharge pipe 81. By opening / closing the valve 83 for the bead discharge pipe, the flow of the bead 1 flowing along the bead discharge pipe 81 can be interrupted.

The air discharge pipe 85 has a hollow pipe or duct shape. The air discharge pipe 85 is connected to the upper portion of the reservoir 50, and serves to guide the flow of air discharged from the reservoir 50.

The air discharge pipe 85 is provided with an air discharge pipe valve 87 for opening and closing the air discharge pipe 85. By opening / closing the valve 87 for the air discharge pipe, the flow of air flowing along the air discharge pipe 85 can be interrupted.

The air flow tube 91 has a hollow pipe or duct shape. The air flow tube 91 is connected to the air inlet 15, and serves to guide the flow of air flowing through the air flow tube 91.

The air flow pipe 91 is provided with an air flow pipe valve 93 for opening and closing the air flow pipe 91. By the opening and closing operation of the valve 93 for the air flow pipe, it becomes possible to interrupt the flow of air flowing along the air flow pipe 91.

The communication tube 95 is connected to the air flow tube 91 and the air discharge tube 85 so as to communicate with the air flow tube 91 and the air discharge tube 85.

Here, the double glazing insulation system according to an embodiment of the present invention further includes a bead recovery pipe (79a) and the valve for the bead recovery pipe (79b). The bead recovery pipe 79a and the bead recovery pipe valve 79b may be selectively provided.

The bead recovery pipe 79a has a hollow pipe or duct shape and is branched from the bead flow pipe 71 to be connected to the upper region of the reservoir 50. The bead recovery pipe 79a guides the plurality of beads 1 flowing out of the chamber 11 and flowing through the bead discharge pipe 81 to be introduced into the upper region of the storage tank 50 through the bead flow pipe 71. Do it. Here, although not shown, the bead recovery pipe 79a may be branched from the bead supply pipe 75 and connected to the upper region of the reservoir 50 without being branched from the bead flow pipe 71.

The bead recovery pipe valve 79b is provided in the bead recovery pipe 79a to open and close the bead recovery pipe 79a. By opening and closing the bead recovery pipe valve 79b, the flow of the beads 1 flowing along the bead recovery pipe 79a can be interrupted.

The main blower 97 is provided in the communication tube 95 to suck air in the chamber 11 through the air flow tube 91 or to suck air in the chamber 11 through the air discharge pipe 85. Here, the main blower 97 may be a conventional blower, a blower, an air compressor, a pump or the like.

Meanwhile, when the main blower 97 sucks air in the chamber 11 through the air flow tube 91, the plurality of beads 1 stored in the storage tank 50 are filled in the chamber 11. At this time, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 are opened, and the bead discharge pipe valve 83 and the air discharge pipe valve 87 are closed.

When the main blower 97 sucks air in the chamber 11 through the air discharge pipe 85, the plurality of beads 1 filled in the chamber 11 are discharged from the chamber 11 to store the tank 50. Save it to At this time, the bead flow pipe valve 73, the bead discharge pipe valve 83, and the air discharge pipe valve 87 are opened, and the bead supply pipe valve 77 and the air flow pipe valve 93 are closed.

In addition, the double glazing insulation system according to the first embodiment of the present invention further includes a branch pipe 101, a branch pipe valve 103, and an auxiliary blower 105.

Branch pipe 101 has a hollow pipe or duct shape. Branch pipe 101 is branched from the air flow pipe 91, serves to guide the flow of air.

The branch valve 103 is provided in the branch pipe 101 to open and close the branch pipe 101. By the opening-closing operation of the branch valve 103, the flow of air flowing along the branch pipe 101 is interrupted.

The auxiliary blower 105 is provided in the branch pipe 101, and blows and blows the pressure into the chamber 11 through the branch pipe 101 and the air flow pipe 91. The air flowing into the chamber 11 through the branch pipe 101 and the air flow tube 91 by the auxiliary blower 105 passes through each air through hole of the bead blocking member 17 for the chamber and follows the window surface. It flows into the chamber 11 and removes the residual beads 1 attached by the electrostatic force to each glass window surface and flows together with the residual beads 1 through the bead outlet 19 to the bead discharge pipe 81. Here, the air filter 107 for filtering the air flowing through the branch pipe 101 may be provided at the front end of the auxiliary blower 105.

In addition, some air flowing along the air flow pipe 91 through the branch pipe 101 by the auxiliary blower 105 flows into the chamber air inlet pipe 31, and the bead provided in the bottom region of the chamber 11. By being fed toward the outlet 19, the plurality of beads 1 filled in the chamber 11 are discharged through the bead outlet 19 into the bottom region opposite the bead outlet 19 of the chamber 11. 1) is stacked obliquely and is not stagnant, is quickly discharged to the reservoir 50 through the bead outlet 19. This makes it possible to eliminate the beads 1 remaining in the bottom region of the chamber 11.

Accordingly, upon discharging the plurality of beads 1 from the chamber 11 of the double glazing 10, the bead outlet 19 of the chamber 11 as well as the remaining beads 1 attached to the glass pane surface of the double glazing 10. By minimizing the residual beads (1) located in the bottom region of the opposite side of the, it is possible to keep the glass window clean.

Here, the auxiliary blower 105 may be a conventional blower, a blower, an air compressor, a pump or the like.

In addition, the double glazing insulation system according to the first embodiment of the present invention further includes an auxiliary air flow pipe 111 and an auxiliary air flow pipe valve 113.

The auxiliary air flow pipe 111 has a hollow pipe or duct shape. The auxiliary air flow pipe 111 is connected to the lower end of the branch pipe 101 and the bead flow pipe 71 or the reservoir 50, the bead flow pipe 71 or the reservoir 50 to the air blown from the auxiliary blower 105 It serves to guide the flow to the bottom of the. Auxiliary air flow pipe 111 is installed in the portion that borders the bead flow pipe 71 or the bottom of the reservoir 50 to the net made of a hole smaller than the beads 1 to block the flow of the beads (1).

The auxiliary air flow pipe valve 113 is provided in the auxiliary air flow pipe 111 to open and close the auxiliary air flow pipe 111. By opening and closing the auxiliary air flow pipe valve 113, the flow of air introduced into the bead flow pipe 71 along the auxiliary air flow pipe 111 can be interrupted.

As described above, when the air blown by the auxiliary blower 105 is introduced into the lower portion of the bead flow tube 71 or the storage tank 50 through the auxiliary air flow tube 111, the filling chamber 1 is filled with the beads 1, and the storage tank is filled. By improving the fluidity of the plurality of beads 1 discharged from the 50, the plurality of beads 1 can flow smoothly from the reservoir 50 along the bead flow tube 71 to the chamber 11.

Here, the auxiliary air flow pipe 111 and the auxiliary air flow pipe valve 113 may be selectively provided as necessary.

In addition, the double glazing insulation system according to the first embodiment of the present invention further includes an auxiliary bead discharge pipe 115 and an auxiliary bead discharge pipe valve 117.

The auxiliary bead discharge pipe 115 has a hollow pipe or duct shape. The auxiliary bead discharge pipe 115 is connected to the bottom of the chamber 11 and the bead flow pipe 71 to guide the plurality of beads 1 discharged from the chamber 11 to the reservoir 50 to flow.

The auxiliary bead discharge pipe valve 117 is provided in the auxiliary bead discharge pipe 115 to open and close the auxiliary bead discharge pipe 115. By opening and closing the auxiliary bead discharge pipe valve 117, the flow of the beads 1 introduced into the bead flow pipe 71 along the auxiliary bead discharge pipe 115 can be interrupted.

As such, by further providing the auxiliary bead discharge pipe 115, when the plurality of beads 1 filled in the chamber 11 is discharged to the reservoir 50 through the bead discharge port 19, it serves as a bypass discharge, The bottleneck generated at the bead outlet 19 can be prevented.

Here, the auxiliary bead discharge pipe 115 and the auxiliary bead discharge pipe valve 117 may be selectively provided as necessary.

In addition, the double glazing insulation system according to the first embodiment of the present invention, minimizing the static electricity to minimize the static electricity generated when the plurality of beads (1) collide with each other and reciprocate between the chamber (11) and the reservoir (50) The device is provided.

As the static electricity minimizer, the ion generator 121, the temperature controller 123, and the humidity controller 125 are included. The ion generator 121, the temperature controller 123 and the humidity controller 125 are provided in the branch pipe 101, respectively, the ion generator 121 ionizes the air flowing through the branch pipe 101, 123 adjusts the temperature of the air flowing through the branch pipe 101, the humidity controller 125 adjusts the humidity of the air flowing through the branch pipe (101).

Here, a heater and a cooler may be provided as the temperature controller 123, and a dehumidifier and a humidifier may be provided as the humidity controller 125.

In addition, the static electricity minimizing device includes a temperature measuring sensor 131, a humidity measuring sensor 133, and an electrostatic measuring sensor 135. The temperature measuring sensor 131, the humidity measuring sensor 133, and the electrostatic measuring sensor 135 are respectively provided in the storage tank 50, and the temperature measuring sensor 131 measures the temperature inside the storage tank 50, and measures the humidity. The sensor 133 measures humidity inside the reservoir 50, and the electrostatic measurement sensor 135 measures static electricity between the plurality of beads 1 accommodated in the reservoir 50.

As a result, before discharging the plurality of beads 1 stored in the reservoir 50 into the chamber 11, the electrostatic measuring sensor 135 measures the static electricity of the beads 1 stored in the reservoir 50, so that the beads ( If the static electricity value of 1) is greater than or equal to the reference value, the auxiliary blower 105, the ion generator 121, the stirrer drive motor 65 of the stirrer 61, and the main blower 97 are controlled by a control unit (not shown). ). At this time, based on the temperature data and the humidity data measured by the temperature measuring sensor 131 and the humidity measuring sensor 133 provided in the storage tank 50, the static electricity between the beads 1 stored in the storage tank 50, respectively. The temperature and humidity of the air flowing through the branch pipe 101 is adjusted so as not to occur.

The auxiliary air flow pipe valve 113 is opened so that the air ionized by the ion generator 121 is supplied to the inside of the storage tank 50 through the auxiliary air flow pipe 111, and the valve 103 for the branch pipe is opened. To close it.

In addition, the air discharge pipe valve 87 is opened to discharge the air introduced into the reservoir 50 to the outside through the main blower 97 through the air discharge pipe 85 and the communication pipe (95). At this time, the valve 93 for the air flow pipe is closed.

Meanwhile, the bead 1 being stirred by the stirrer 61 in the reservoir 50 is mixed with the ionized air introduced into the reservoir 50 to minimize static electricity. When the static electricity value measured by the static electricity measuring sensor 135 is equal to or less than the reference value, the auxiliary blower 105, the ion generator 121, the stirrer drive motor 65 of the stirrer 61, and the main blower Shut down the device 97.

As a result, the plurality of beads 1 stored in the reservoir 50 may be stored with the static electricity minimized.

As such, by providing the static electricity minimizing apparatus, the static electricity generated in the beads 1 is minimized to prevent the beads 1 from tangling with each other due to the electrostatic force between the beads 1, and the beads 1 in the bead flow tube 71. ) Can reduce bottlenecks. In addition, the bead 1 in the chamber 11 or the reservoir 50 flows smoothly and is discharged to prevent bottlenecks and to keep the glass window clean, thereby improving user convenience and power of the main blower 97. You can improve the overall system performance by reducing the consumption.

On the other hand, in the double-window insulation system according to the first embodiment of the present invention, the rotary feeder 141 for the storage tank is provided at the lower end of the storage tank 50, the bead at the connection portion of the bead outlet 19 and the bead discharge pipe 81 The discharge pipe rotary feeder 143 may be provided, and the auxiliary bead discharge pipe rotary feeder 145 may be provided at a connection portion between the bottom of the chamber 11 and the auxiliary bead discharge pipe 115.

As a result, when the plurality of beads 1 are withdrawn into the storage tank 50, the plurality of beads 1 are introduced into the bead flow tube 71 or the storage tank 50 by a predetermined amount by the storage rotary feeder 141. As a result, bottlenecks may be reduced in the bead outlet region of the reservoir 50.

In addition, when storing the plurality of beads 1 filled in the chamber 11 in the reservoir 50, the plurality of beads 1 filled in the chamber 11 is discharged to the rotary feeder 143 for the bead discharge pipe and the auxiliary bead discharge The rotary rotary feeder 145 is introduced into the bead discharge pipe 81 and the auxiliary bead discharge pipe 115 by a predetermined amount, respectively, to reduce the occurrence of bottlenecks in the bead outlet region of the chamber 11.

Here, in the present embodiment, the rotary feeder 141 for the storage tank is provided at the lower end of the reservoir 50, and the rotary feeder 143 for the discharge pipe is provided at the connection portion between the bead discharge port 19 and the bead discharge pipe 81. In addition, although the rotary feeder 145 for the auxiliary bead discharge pipe is provided at the connection portion between the bottom of the chamber 11 and the auxiliary bead discharge pipe 115, the present invention is not limited thereto, and instead of the rotary feeder, slide gates may be provided. Can be.

On the other hand, the above-described bead flow pipe 71, bead supply pipe 75, bead discharge pipe 81, air discharge pipe 85, air flow pipe 91, communication pipe 95, branch pipe 101, auxiliary air flow pipe 111 ), The reservoir air inlet pipe 53, the chamber air inlet pipe 31, and the auxiliary bead discharge pipe 115 are effectively made of a conductive material to minimize static electricity. In addition, the above-described bead flow pipe valve 73, bead supply pipe valve 77, bead discharge pipe valve 117, air discharge pipe valve 87, air flow pipe valve 93, branch pipe valve 103 , The auxiliary air flow pipe valve 113, the reservoir air inlet pipe valve 55, the chamber air inlet pipe valve 33, and the auxiliary bead discharge pipe valve 117 may be opened or closed by driving of a solenoid valve or a motor. It can be made of a motor-driven valve.

With this configuration, the operation of the double glazing insulation system according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3 as follows.

First, as shown in FIG. 1, a plurality of beads 1 are stored in a reservoir 50, and a chamber 11 of the double glazing 10 is not filled with a plurality of beads 1. The process of filling the some bead 1 with (11) is demonstrated.

Prior to filling the plurality of beads 1 into the chamber 11, the drive motor 175 for the wire drum is operated to position the movable body 160 in the center of the chamber 11.

The bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 are opened, and the bead discharge pipe valve 83, the auxiliary bead discharge pipe valve 117, and the air discharge pipe valve 87 ) And the main blower 97 are operated with the bead recovery pipe valve 79b closed.

As the main blower 97 is operated, as shown in FIG. 2, the main blower 97 includes a communication tube 95, an air flow tube 91, a chamber 11, a bead supply tube 75, The air present in the bead flow tube 71 is sucked in. At this time, since the valve 87 for the air discharge pipe is closed, the air inside the reservoir 50 is not sucked by the main blower 97 through the air discharge pipe 85.

Due to the suction action of the main blower 97, a negative pressure is generated in the communication pipe 95, the air flow pipe 91, the chamber 11, the bead supply pipe 75, and the bead flow pipe 71. The plurality of beads 1 stored in the 50 flows along the bead flow pipe 71 and the bead supply pipe 75 to flow into the upper region of the chamber 11. At this time, the maximum negative pressure is generated in the center of the chamber 11 due to the suction pressure of the main blower 97, but the movable body 160 is located in the center of the chamber 11 to close the gap between the pair of glass windows. By retaining, the movable body 160 serves as a pillar supporting the pair of glass windows, so that the contraction phenomenon does not occur in the central region of the chamber 11, thereby reducing the breakage of the glass window. The wire drum driving motor is based on the pressure value inside the chamber 11 measured by the pressure measuring sensor 21 and the bead filling distance value inside the chamber 11 measured by the distance measuring sensor 23. The movable body 160 is elevated by rotating 175 in one direction or the other direction.

On the other hand, during or before the plurality of beads 1 are introduced into the chamber 11, the reservoir air inlet pipe valve 55 provided in the reservoir air inlet pipe 53 is opened, and is relatively relatively to the reservoir 50. By flowing the outside air having a high pressure above the plurality of beads 1 stored in the storage tank 50, the plurality of beads 1 stored in the storage tank 50 can be smoothly discharged from the storage tank 50 without a bottleneck. It may be.

In addition, by opening the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111, the auxiliary blower 105 is operated to blow air into the auxiliary air flow pipe 111, the auxiliary blower 105 By introducing the air blown into the bead flow tube 71 through the auxiliary air flow tube 111, the fluidity of the plurality of beads 1 discharged from the reservoir 50 is improved, the plurality of beads 1 is stored in the reservoir 50 ) May smoothly flow into the chamber 11 along the bead flow tube 71. At this time, the valve 103 for branch pipes provided in the branch pipes 101 is closed to prevent the air blown from the auxiliary blower 105 from flowing into the air flow pipe 91 through the branch pipes 101.

The plurality of beads 1 introduced into the chamber 11 free fall from the upper end of the double glazing 10 toward the lower end and are filled in the entire region of the chamber 11 as shown in FIG. 2. At this time, the plurality of beads 1 filled in the chamber 11 is prevented from leaking to the air flow tube 91 by the chamber bead blocking member 17 provided in the air inlet and outlet 15.

The air introduced into the chamber 11 together with the plurality of beads 1 passes through the chamber bead blocking member 17 and is discharged to the outside through the main blower 97 through the air flow pipe 91. .

After the plurality of beads 1 stored in the reservoir 50 are filled into the entire region of the chamber 11, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 that have been opened. At the same time, the reservoir air inlet pipe valve 55 and the auxiliary air flow pipe valve 113 are closed at the same time.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads (1) is filled, thereby insulating, shading and sound insulation through the double window (10) It can be improved, and no additional installation of curtains or blinds is necessary. In particular, the movable body 160 is located in the center of the chamber 11, thereby preventing the chamber 11 of the double window 10 from contracting, thereby reducing breakage of the glass window.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b are not provided in this embodiment, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 are provided. The main blower 97 is operated while the valve 83 for the bead discharge pipe 83, the valve for the auxiliary bead discharge pipe 117 and the valve 87 for the air discharge pipe are closed. The beads 1 may be introduced into the upper region of the chamber 11 through the bead flow tube 71 and the bead supply tube 75, so that the plurality of beads 1 may be filled in the chamber 11.

Hereinafter, as shown in FIG. 2, the process of discharging the plurality of beads 1 to the reservoir 50 while the plurality of beads 1 are filled in the chamber 11 of the double window 10 will be described. do.

As shown in FIG. 3, the bead flow pipe valve 73, the bead discharge pipe valve 83, the air discharge pipe valve 87, and the bead recovery pipe valve 79b are opened, and the air flow pipe valve 93 is opened. In the closed state, the main blower 97 is operated.

Meanwhile, the auxiliary air blower 105 is opened after opening the chamber air inlet pipe valve 33 or opening the branch pipe valve 103 during or before the plurality of beads 1 are introduced into the storage tank 50. It can also operate to supply external air to the chamber (11).

As the main blower 97 operates, the main blower 97 includes a communication pipe 95, an air discharge pipe 85, a reservoir 50, a bead flow pipe 71, and a bead recovery pipe 79a. And the air present in the bead supply pipe 75, the bead discharge pipe 81, and the chamber 11 are sucked in. At this time, since the valve 93 for the air flow pipe is closed, the air of the chamber 11 is not sucked into the main blower 97 through the air flow pipe 91.

By the suction action of the main blower 97, the communication pipe 95, the air discharge pipe 85, the storage tank 50, the bead flow pipe 71, the bead recovery pipe 79a, the bead discharge pipe 81 And a negative pressure is generated in the chamber 11, and some of the beads 1 filled in the chamber 11 flow through the bead discharge pipe 81 along the bead flow pipe 71 and flow into the bottom of the reservoir 50. The remaining beads 1 flow along the bead flow pipe 71 and the bead recovery pipe 79a through the bead discharge pipe 81 and flow into the upper portion of the storage tank 50.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b are not provided in this embodiment, the bead flow pipe valve 73, the bead discharge pipe valve 83 and the air discharge pipe valve 87 In the state of closing the valve 93 for the air flow pipe, and operating the main blower 97, the bead 1 filled in the chamber 11 is connected to the bead discharge pipe 81 and the bead flow pipe 71. It flows in into the bottom part of the storage tank 50, and can discharge the some bead 1 from the chamber 11 through.

After discharging the plurality of beads 1 from the chamber 11, some of the beads 1 are attached to the window surface by electrostatic force or remain in the bottom region of the chamber 11.

Accordingly, the valve 103 for branch pipes and the valve 33 for chamber air inlet pipes are opened, and the auxiliary blower 105 is further operated. At this time, the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111 is closed, so that the air blown from the auxiliary blower 105 flows through the auxiliary air flow pipe 111 through the bead flow pipe 71 or the storage tank 50. Do not flow into).

As the auxiliary blower 105 is operated, the auxiliary blower 105 blows air toward the branch pipe 101, and some air blown into the branch pipe 101 passes through the air flow pipe 91 for the chamber. It passes through each air through hole of the bead blocking member 17 and enters the chamber 11 along the window surface to remove the remaining beads 1 attached to each window surface by electrostatic force, and the remaining beads 1 are It flows to the bead discharge pipe 81 through the bead discharge port (19).

In addition, the remaining air blown into the branch pipe 101 flows into the bottom region of the chamber 11 through the chamber air inlet pipe 31. Outside air having a higher pressure than the chamber 11 is introduced into the bottom region of the chamber 11 and injected toward the bead outlet 19, thereby beading to the bottom region opposite the bead outlet 19 of the chamber 11. (1) is stacked obliquely and does not stagnate, and is quickly discharged to the reservoir 50 through the bead outlet 19, so that the beads 1 remain in the bottom region of the chamber 11 can be eliminated.

This minimizes the amount of beads 1 attached to the glass pane surface of the double pane 10 and the beads 1 remaining in the bottom region of the chamber 11, thereby keeping the glass pane clean. Then, the drive motor 175 for the wire drum is operated to accommodate the movable body 160 in the movable body accommodating part 27.

Meanwhile, the plurality of beads 1 discharged from the chamber 11 and stored in the storage tank 50 are prevented from leaking to the air discharge pipe 85 by the storage bead blocking member 51 provided in the storage tank 50. .

In addition, the air introduced into the storage tank 50 together with the plurality of beads 1 passes through the storage bead blocking member 51 and passes through the air discharge pipe 85 and the communication pipe 95 to pass through the main blower 97. Through the outside.

After the plurality of beads 1 discharged from the chamber 11 are stored in the reservoir 50, the bead flow pipe valve 73, the bead discharge pipe valve 83, and the air discharge which have been opened as shown in FIG. 1. The pipe valve 87 and the bead recovery pipe valve 79b are closed, and the branch pipe valve 103 is closed at the same time.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads 1 are discharged, it can be viewed through the double window (10).

9-14 illustrate a double glazing insulation system according to a second embodiment of the present invention.

Unlike the first embodiment described above, the double glazing insulation system according to the second embodiment of the present invention allows the movable body 160 to move in the left and right directions of the chamber 11, for example, to approach and to the bead inlet 13. It is possible.

The movable body 160 has a rectangular plate shape having a size corresponding to the thickness of the pair of glass windows. The movable body 160 has a length such that interference with the bead blocking member 17 and the bead outlet 19 for the chamber does not occur.

The movable body moving unit 170b includes a pair of screw shafts 181 for movable bodies and a pair of screw shaft drive motors 183 for movable bodies.

The pair of screw shafts 181 for the movable body are arranged side by side at a distance from each other in the vertical direction of the chamber 11, for example, horizontally with respect to the movable body 160. Each screw shaft 181 for the movable body is screwed to the movable body 160 so as to be screwable.

The screw shaft drive motor 183 for the mobile body is coupled to the screw shaft 181 for the mobile body, and rotates the screw shaft 181 for the mobile body forward and backward.

Thus, when the screw shaft drive motor 183 for the movable body is rotated in one direction, the movable body moves toward the bead inlet 13. In addition, when the screw shaft drive motor 183 for the movable body is rotated in the other direction, the movable body 160 moves to be spaced apart from the bead inlet 13.

In addition, the double glazing insulation system according to the second embodiment of the present invention further includes a guide 189 for guiding the movement of the moving body 160.

The guide 189 has a rod shape, and the movable body 160 is movably coupled thereto. The guide 189 is provided along the moving direction of the movable body 160, for example, arranged side by side with the screw shaft 181 for the movable body to guide the movement of the movable body 160.

In addition, in the double glazing insulation system according to the second embodiment of the present invention, unlike the first embodiment described above, the bead blocking member 17 for the chamber is disposed in the upper region of the chamber 11. In addition, the air flow pipe connected to the upper portion of the chamber 11 is branched into the first air flow pipe (91a) and the second air flow pipe (91b). The first air flow tube 91a and the second air flow tube 91b are connected to the chamber 11 at intervals along the transverse direction of the chamber 11. The first air flow pipe 91a is provided with a first air flow pipe valve 93a for opening and closing the first air flow pipe 91a, and the second air flow pipe 91b is provided with a second air flow pipe 91b. A valve 93b for two air flow pipes is provided.

Here, the movable body moving unit 170b in the present embodiment is composed of a movable screw shaft 181 and a movable screw shaft drive motor 183, but is not limited thereto, and the movable body moving unit 170b is not shown. However, it may be composed of a drive rod connected to the moving body, and an actuator for linearly reciprocating the moving body by extending and reducing the length of the driving rod.

By this configuration, the operation of the double glazing insulation system according to the second embodiment of the present invention will be described.

First, as shown in FIG. 9, the plurality of beads 1 are stored in the reservoir 50, and the chamber 11 of the double glazing 10 is not filled with the plurality of beads 1. The process of filling the some bead 1 with (11) is demonstrated.

Prior to filling the plurality of beads 1 into the chamber 11, the movable screw shaft drive motor 183 is operated to bring the movable body 160 closer to the center of the chamber 11.

The bead flow pipe valve 73, the bead supply pipe valve 77, the air flow pipe valve 93, and the first air flow pipe valve 93a are opened, and the bead discharge pipe valve 83 and the auxiliary bead discharge pipe valve The main blower 97 is operated in the state in which 117, the air discharge pipe valve 87, the second air flow pipe valve 93b, and the bead recovery pipe valve 79b are closed.

As the main blower 97 operates, as shown in FIG. 10, the main blower 97 includes a communication tube 95, an air flow tube 91, a first air flow tube 91a, and a chamber 11. ), The bead supply pipe 75, and the air present in the bead flow pipe 71 are sucked in. At this time, since the valve 87 for the air discharge pipe is closed, the air inside the reservoir 50 is not sucked by the main blower 97 through the air discharge pipe 85.

By the suction action of the main blower 97, the communication pipe 95, the air flow pipe 91, the first air flow pipe 91a, the chamber 11, the bead supply pipe 75, and the bead flow pipe 71 Negative pressure is generated, and the plurality of beads 1 stored in the reservoir 50 flow along the bead flow tube 71 and the bead supply tube 75 and flow into the upper region of the chamber 11. At this time, the maximum negative pressure is generated in the chamber 11 by the suction pressure of the main blower 97, but the movable body 160 maintains the distance between the pair of glass windows, so that the movable body 160 has a pair of It serves as a pillar to support the glass window, the shrinkage phenomenon does not occur in the chamber 11, thereby reducing the damage to the glass window.

The screw shaft for the moving object is based on the pressure value inside the chamber 11 measured by the pressure measuring sensor 21 and the bead filling distance value inside the chamber 11 measured by the distance measuring sensor 23. The chamber 11 between the movable body 160 and the bead inlet 13 as shown in FIG. 11 while the driving motor 183 is rotated in the other direction to move the movable body 160 to be spaced apart from the bead inlet 13. The beads 1 are filled into the area. When the movable body 160 moves from the center of the chamber 11 to the opposite side of the bead inlet 13, the second air flow valve 93b is further opened to open the gap between the movable body 160 and the bead inlet 13. Air present in the chamber 11 is sucked into the air flow tube 91 via the first air flow tube 91a and the second air flow tube 91b.

On the other hand, during or before the plurality of beads 1 are introduced into the chamber 11, the reservoir air inlet pipe valve 55 provided in the reservoir air inlet pipe 53 is opened, and the plurality of beads 1 stored in the reservoir 50 are stored. The beads 1 may be smoothly discharged from the reservoir 50 without the bottleneck.

In addition, by opening the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111, the auxiliary blower 105 is operated to blow air into the auxiliary air flow pipe 111, the auxiliary blower 105 The blown air may be introduced into the bead flow tube 71 via the auxiliary air flow tube 111. At this time, the valve 103 for branch pipes provided in the branch pipes 101 is closed to prevent the air blown from the auxiliary blower 105 from flowing into the air flow pipe 91 through the branch pipes 101.

The plurality of beads 1 introduced into the chamber 11 region between the movable body 160 and the bead inlet 13 freely fall from the upper end of the double glazing 10 toward the lower end and are filled into the entire region of the chamber 11. . At this time, the plurality of beads 1 filled in the chamber 11 is prevented from leaking to the air flow tube 91 by the chamber bead blocking member 17 provided in the air inlet and outlet 15.

The air introduced into the chamber 11 together with the plurality of beads 1 passes through the chamber bead blocking member 17 and is discharged to the outside through the main blower 97 through the air flow pipe 91. .

After the plurality of beads 1 stored in the reservoir 50 are filled into the entire region of the chamber 11, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 that have been opened. And the first air flow pipe valve 93a and the second air flow pipe valve 93b, and at the same time, the reservoir air inlet pipe valve 55 and the auxiliary air flow pipe valve 113 are closed.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads (1) is filled, thereby insulating, shading and sound insulation through the double window (10) It can be improved, and no additional installation of curtains or blinds is necessary. In particular, when the bead 1 is filled in the chamber 11, the movable body 160 moves away from the bead inlet 13 while maintaining a distance between the pair of glass windows, so that the chamber 11 of the double window 10 is moved. By preventing shrinkage, breakage of the glass window can be reduced.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b are not provided in this embodiment, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 are provided. The main blower 97 is operated while the valve 83 for the bead discharge pipe 83, the valve for the auxiliary bead discharge pipe 117 and the valve 87 for the air discharge pipe are closed, and the valve for the first air flow pipe 93a. ) And the second air flow valve (93b) is selectively opened and closed according to the movement of the moving body 160, and the plurality of beads (1) stored in the reservoir (50) is connected to the bead flow pipe (71) and the bead supply pipe (75). After passing through the upper region of the chamber 11, the plurality of beads 1 may be filled in the chamber 11.

Hereinafter, as illustrated in FIG. 11, a process of discharging the plurality of beads 1 to the reservoir 50 while the plurality of beads 1 are filled in the chamber 11 of the double window 10 will be described. do.

As shown in FIG. 12, the bead flow pipe valve 73, the bead discharge pipe valve 83, the air discharge pipe valve 87, and the movable body 160 are spaced at the maximum distance from the bead inlet 13. The main blower 97 is opened while the bead recovery pipe valve 79b is opened and the air flow pipe valve 93, the first air flow pipe valve 93a, and the second air flow pipe valve 93b are closed. It works. Meanwhile, after the plurality of beads 1 are introduced into the storage tank 50 or before the plurality of beads 1 are introduced, the auxiliary air blower 105 is opened after opening the valve air inlet pipe 33 or the branch valve 103. It is also possible to supply external air to the chamber 11 by operating the.

As the main blower 97 operates, the main blower 97 includes a communication pipe 95, an air discharge pipe 85, a reservoir 50, a bead flow pipe 71, and a bead recovery pipe 79a. And the bead discharge pipe 81 and the air present in the chamber 11 are sucked in. At this time, since the valve 93 for the air flow pipe is closed, the air of the chamber 11 is not sucked into the main blower 97 through the air flow pipe 91.

By the suction action of the main blower 97, the communication pipe 95, the air discharge pipe 85, the storage tank 50, the bead flow pipe 71, the bead recovery pipe 79a, the bead discharge pipe 81 And, the negative pressure is generated in the chamber 11, the bead 1 filled in the chamber 11 flows along the bead flow pipe 71 through the bead discharge pipe 81 and flows into the bottom of the reservoir 50 The remaining beads 1 flow along the bead flow pipe 71 and the bead recovery pipe 79a through the bead discharge pipe 81 and flow into the upper portion of the storage tank 50.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b are not provided in this embodiment, the bead flow pipe valve 73, the bead discharge pipe valve 83 and the air discharge pipe valve 87 In the state of closing the valve 93 for the air flow pipe, and operating the main blower 97, the bead 1 filled in the chamber 11 is connected to the bead discharge pipe 81 and the bead flow pipe 71. It flows in into the bottom part of the storage tank 50, and can discharge the some bead 1 from the chamber 11 through.

After discharging the plurality of beads 1 from the chamber 11, some of the beads 1 are attached to the window surface by electrostatic force or remain in the bottom region of the chamber 11.

Accordingly, the valve 103 for branch pipes, the valve 33 for chamber air inlet pipes, the valve 93a for first air flow pipes, and the valve 93b for second air flow pipes are opened, and an auxiliary blower 105 is further added. It works. At this time, the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111 is closed, so that the air blown from the auxiliary blower 105 flows through the auxiliary air flow pipe 111 through the bead flow pipe 71 or the storage tank 50. Do not flow into).

As the auxiliary blower 105 is operated, the auxiliary blower 105 blows air toward the branch pipe 101, and some air blown into the branch pipe 101 passes through the air flow pipe 91 and the first air. It passes through the air through hole of the bead blocking member 17 for the chamber through the flow pipe 91a and the second air flow pipe 91b, and flows into the chamber 11 along the window surface, and is attached to each window surface by electrostatic force. The remaining beads 1 are removed, and the remaining beads 1 flow through the bead outlet 19 to the bead discharge pipe 81.

In addition, the remaining air blown into the branch pipe 101 flows into the bottom region of the chamber 11 through the chamber air inlet pipe 31. Outside air having a higher pressure than the chamber 11 is introduced into the bottom region of the chamber 11 and injected toward the bead outlet 19, thereby beading to the bottom region opposite the bead outlet 19 of the chamber 11. (1) is stacked obliquely and does not stagnate, and is quickly discharged to the reservoir 50 through the bead outlet 19, so that the beads 1 remain in the bottom region of the chamber 11 can be eliminated.

13 and 14, the screw shaft drive motor 183 for the movable body is rotated in one direction to move the movable body 160 to approach the bead inlet 13, and thus, to the electrostatic force on each glass window surface. By forcibly detaching the remaining beads 1 attached thereto, the remaining beads 1 flow through the bead outlet 19 to the bead discharge pipe 81 and keep the glass window clean. Here, the first air flow pipe valve 93a and the second air flow pipe valve 93b are closed to prevent air from flowing into the chamber 11 through the first air flow pipe 91a and the second air flow pipe 91b. In the non-moving state, the mobile body 160 is moved toward the bead inlet 13 while being in close contact with the window surface, that is, scraping the window surface with the mobile body 160, forcibly detaching the remaining beads 1 attached to the window surface. You can also

Meanwhile, the plurality of beads 1 discharged from the chamber 11 and stored in the storage tank 50 are prevented from leaking to the air discharge pipe 85 by the storage bead blocking member 51 provided in the storage tank 50. .

In addition, the air introduced into the storage tank 50 together with the plurality of beads 1 passes through the storage bead blocking member 51 and passes through the air discharge pipe 85 and the communication pipe 95 to pass through the main blower 97. Through the outside.

After the plurality of beads 1 discharged from the chamber 11 are stored in the reservoir 50, the bead flow pipe valve 73, the bead discharge pipe valve 83, and the air discharge which were opened as shown in FIG. The pipe valve 87 and the bead recovery pipe valve 79b are closed, and the branch pipe valve 103 is closed at the same time.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads 1 are discharged, it can be viewed through the double window (10).

15 to 20 show a double glazing insulation system according to a third embodiment of the present invention.

In the double-window insulation system according to the third embodiment of the present invention, unlike the first embodiment described above, the movable body 160 corresponds to the thickness of the pair of glass windows 10a (see FIG. 20) and the width of the chamber 11. It has a rectangular plate shape of size. Here, as illustrated in FIGS. 21 and 22, the movable body 160 includes four sealing members 165 that can be pulled out along each side of the double window 10, and each sealing member 165 is sealed. By the operation of the member drive motor 167, it protrudes from each side of the moving body 160 to be in close contact with the glass window 10a, and seals the glass window 10a.

In addition, in the double-window insulation system according to the third embodiment of the present invention, unlike the first embodiment described above, the bead supply pipe 75 connected to the chamber 11 includes a first bead supply pipe 75a and a second bead supply pipe ( Branch to 75b). The first bead supply pipe (75a) and the second bead supply pipe (75b) are connected to the first bead inlet (13a) and the second bead inlet (13b) formed at intervals in the vertical direction of the chamber (11), respectively. The first bead supply pipe (75a) is provided with a valve for the first bead supply pipe (77a) for opening and closing the first bead supply pipe (75a), the second bead supply pipe (75b) for opening and closing the second bead supply pipe (75b) A valve for the two bead supply pipe 77b is provided.

In addition, unlike the first embodiment described above, in the double-window insulation system according to the third embodiment of the present invention, the air flow pipe 91 connected to the chamber 11 includes the first air flow pipe 91a and the second air flow pipe ( Branch to 91b). The first air flow tube 91a and the second air flow tube 91b are connected to the first air inlet 15a and the second air inlet 15b which are formed at intervals in the vertical direction of the chamber 11, respectively. The first air flow pipe 91a is provided with a first air flow pipe valve 93a for opening and closing the first air flow pipe 91a, and the second air flow pipe 91b is provided with a second air flow pipe 91b. A valve 93b for two air flow pipes is provided.

In addition, the double glazing 10 includes a bottom of the chamber 10 and a space between the first bead inlet 13a and between the first bead inlet 13a and the second bead inlet 13b, respectively. The pressure measuring sensor 21 which measures a pressure, and the distance measuring sensor 23 which measures the filling distance of the bead 1 inside the chamber 11 are provided.

By this configuration, the operation of the double glazing insulation system according to the third embodiment of the present invention will be described.

First, as shown in FIG. 15, the plurality of beads 1 are stored in the reservoir 50, and the chamber 11 of the double glazing 10 is not filled with the plurality of beads 1. The process of filling the some bead 1 with (11) is demonstrated.

Prior to filling the plurality of beads 1 into the chamber 11, the drive motor 175 for the wire drum is operated to move the movable body 160 above the first bead inlet 13a and the first air inlet 15a. Place it in

Open the bead flow pipe valve 73, the bead supply pipe valve 77, the first bead supply pipe valve 77a, the first air flow pipe valve 93a and the air flow pipe valve 93, The valve 83, the auxiliary bead discharge pipe valve 117, the air discharge pipe valve 87, the second bead supply pipe valve 77b, the second air flow pipe valve 93b and the bead recovery pipe valve 79b In the closed state, the main blower 97 is operated.

As the main blower 97 operates, as shown in FIG. 16, the main blower 97 includes a communication tube 95, an air flow tube 91, a first air flow tube 91a, and a chamber 11. ), The first bead supply pipe 75a, the bead supply pipe 75, and the air present in the bead flow pipe 71 are sucked in. At this time, since the valve 87 for the air discharge pipe is closed, the air inside the reservoir 50 is not sucked by the main blower 97 through the air discharge pipe 85.

By the suction action of the main blower 97, the communication pipe 95, the air flow pipe 91, the first air flow pipe 91a, the chamber 11, the first bead supply pipe 75a, and the bead supply pipe Negative pressure is generated in the 75 and the bead flow tube 71, and the plurality of beads 1 stored in the reservoir 50 connect the bead flow tube 71, the bead supply tube 75, and the first bead supply tube 75 a. It flows along and flows into the middle region of the chamber 11. At this time, the maximum negative pressure is generated in the chamber 11 by the suction pressure of the main blower 97, but the movable body 160 maintains the distance between the pair of glass windows 10a, so that the movable body 160 As a pillar supporting the pair of glass windows 10a, shrinkage does not occur in the chamber 11, thereby reducing damage to the glass windows 10a. Then, the drive for the wire drum is based on the pressure value inside the chamber 11 measured by the pressure measuring sensor 21 and the bead filling distance value inside the chamber 11 measured by the distance measuring sensor 23. By rotating the motor 175 in one direction to move the movable body 160 to the upper portion of the chamber 11, the bead 1 is filled into the chamber 11 region between the bottom of the chamber 11 and the movable body 160 When the moving body 160 passes through the first bead inlet 13a and ascends toward the second bead inlet 13b, the second air flow pipe valve 93b is further opened to open the bottom of the chamber 11. Air existing between the moving body 160 is sucked into the air flow tube 91 via the first air flow tube 91a and the second air flow tube 91b.

Then, when the moving body 160 passes through the second bead inlet 13b while rising to the upper portion of the chamber 11, the second bead supply pipe 77b is further opened to open the bead 1 through the chamber 11. It is supplied between the bottom of the) and the moving body 160.

On the other hand, during or before the plurality of beads 1 are introduced into the chamber 11, the reservoir air inlet pipe valve 55 provided in the reservoir air inlet pipe 53 is opened, and the plurality of beads 1 stored in the reservoir 50 are stored. The beads 1 may be smoothly discharged from the reservoir 50 without the bottleneck.

In addition, by opening the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111, the auxiliary blower 105 is operated to blow air into the auxiliary air flow pipe 111, the auxiliary blower 105 The blown air may be introduced into the bead flow tube 71 via the auxiliary air flow tube 111. At this time, the valve 103 for branch pipes provided in the branch pipes 101 is closed to prevent the air blown from the auxiliary blower 105 from flowing into the air flow pipe 91 through the branch pipes 101.

The plurality of beads 1 introduced into the chamber 11 region between the movable body 160 and each of the bead inlets 13a and 13b free fall from the top of the double glazing 10 toward the bottom as shown in FIG. 17. And is filled into the entire area of the chamber 11. At this time, the plurality of beads 1 filled in the chamber 11 are prevented from leaking into the first air flow tube 91a and the second air flow tube 91b by the chamber bead blocking member 17.

In addition, the air introduced into the chamber 11 together with the plurality of beads 1 passes through the bead blocking member 17 for the chamber, so that the first air flow tube 91a, the second air flow tube 91b, and the air flow tube ( It is discharged to the outside through the main blower 97 through 91).

After the plurality of beads 1 stored in the reservoir 50 are filled into the entire region of the chamber 11, the bead flow pipe valve 73, the bead supply pipe valve 77, and the air flow pipe valve 93 that have been opened. At the same time, the reservoir air inlet pipe valve 55 and the auxiliary air flow pipe valve 113 are closed at the same time.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads (1) is filled, thereby insulating, shading and sound insulation through the double window (10) It can be improved, and no additional installation of curtains or blinds is necessary. In particular, when the bead 1 is filled in the chamber 11, the movable body 160 moves while maintaining the distance between the pair of glass windows 10a, thereby preventing the chamber 11 of the double window 10 from contracting. The breakage of the window can be reduced.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b in this embodiment are not provided, the bead flow pipe valve 73 and the air flow pipe valve 93 are opened, and the bead discharge pipe valve The main blower 97 is operated with the 83 and the auxiliary bead discharge pipe valve 117 and the air discharge pipe valve 87 closed, and the valve for the first bead supply pipe 77a and the second bead supply pipe. The plurality of beads 1 stored in the reservoir 50 are selectively opened and closed while the 77b and the first air flow valve 93a and the second air flow valve 93b are selectively opened and closed according to the movement of the movable body 160. Through the bead flow tube 71 and the bead supply pipe 75 may be introduced into the upper region of the chamber 11, the plurality of beads 1 may be filled in the chamber 11.

Hereinafter, as illustrated in FIG. 17, a process of discharging the plurality of beads 1 to the reservoir 50 while the plurality of beads 1 are filled in the chamber 11 of the double window 10 will be described. do.

As shown in FIG. 18, the bead flow pipe valve 73, the bead discharge pipe valve 83, the air discharge pipe valve 87, and the movable body 160 are raised to the maximum high position of the chamber 11. The bead recovery pipe valve 79b is opened, and the air flow valve valve 93, the first air flow pipe valve 93a, the second air flow pipe valve 93b, the first bead supply pipe valve 77a, and the first The main blower 97 is operated with the two-bead supply pipe valve 77b closed. On the other hand, after the plurality of beads 1 flow into or into the reservoir 50, the auxiliary air blower 105 is opened after opening the valve 33 for the chamber air inlet pipe or opening the valve 103 for the branch pipe. ) May be supplied to supply the outside air to the chamber (11).

As the main blower 97 operates, the main blower 97 includes a communication pipe 95, an air discharge pipe 85, a reservoir 50, a bead flow pipe 71, and a bead recovery pipe 79a. And the bead discharge pipe 81 and the air present in the chamber 11 are sucked in. At this time, since the valve 93 for the air flow pipe, the valve 93a for the first air flow pipe, and the valve 93b for the second air flow pipe are closed, the air in the chamber 11 is discharged from the first air flow pipe 91a and the first air flow pipe 91a. It is not sucked into the main blower 97 through the two air flow tube 91b and the air flow tube 91.

By the suction action of the main blower 97, the communication pipe 95, the air discharge pipe 85, the storage tank 50, the bead flow pipe 71, the bead recovery pipe 79a, the bead discharge pipe 81 And, the negative pressure is generated in the chamber 11, the bead 1 filled in the chamber 11 flows along the bead flow pipe 71 through the bead discharge pipe 81 and flows into the bottom of the reservoir 50 The remaining beads 1 flow along the bead flow pipe 71 and the bead recovery pipe 79a through the bead discharge pipe 81 and flow into the upper portion of the storage tank 50.

Here, when the bead recovery pipe 79a and the bead recovery pipe valve 79b are not provided in this embodiment, the bead flow pipe valve 73, the bead discharge pipe valve 83 and the air discharge pipe valve 87 The valve 93 for the air flow pipe, the valve 93a for the first air flow pipe, the valve 93b for the second air flow pipe, the valve 77a for the first bead supply pipe, and the valve for the second bead supply pipe 77b. ), The main blower 97 is operated, and the beads 1 filled in the chamber 11 flow into the bottom of the storage tank 50 through the bead discharge pipe 81 and the bead flow pipe 71. The plurality of beads 1 can be discharged from the chamber 11.

After discharging the plurality of beads 1 from the chamber 11, some of the beads 1 are attached to the window surface by electrostatic force or remain in the bottom region of the chamber 11.

Accordingly, the valve 103 for branch pipes, the valve 33 for chamber air inlet pipes, the valve 93a for first air flow pipes, and the valve 93b for second air flow pipes are opened, and an auxiliary blower 105 is further added. It works. At this time, the auxiliary air flow pipe valve 113 provided in the auxiliary air flow pipe 111 is closed, so that the air blown from the auxiliary blower 105 flows through the auxiliary air flow pipe 111 through the bead flow pipe 71 or the storage tank 50. Do not flow into).

As the auxiliary blower 105 is operated, the auxiliary blower 105 blows air toward the branch pipe 101, and some air blown into the branch pipe 101 passes through the air flow pipe 91 and the first air. It passes through the air through hole of the bead blocking member 17 for the chamber through the flow pipe 91a and the second air flow pipe 91b, and flows into the chamber 11 along the window surface, and is attached to each window surface by electrostatic force. The remaining beads 1 are removed, and the remaining beads 1 flow through the bead outlet 19 to the bead discharge pipe 81.

In addition, the remaining air blown into the branch pipe 101 flows into the bottom region of the chamber 11 through the chamber air inlet pipe 31. Outside air having a higher pressure than the chamber 11 is introduced into the bottom region of the chamber 11 and injected toward the bead outlet 19, thereby beading to the bottom region opposite the bead outlet 19 of the chamber 11. (1) is stacked obliquely and does not stagnate, and is quickly discharged to the reservoir 50 through the bead outlet 19, so that the beads 1 remain in the bottom region of the chamber 11 can be eliminated.

And, as shown in Figure 19, by rotating the drive motor 175 for the wire drum in the other direction, while the moving body 160 is lowered toward the bottom of the chamber 11, the remaining remaining attached to each window surface by the electrostatic force By forcibly detaching the beads 1, the remaining beads 1 flow through the bead outlet 19 to the bead discharge pipe 81, it is possible to keep the glass window 10a clean. Here, the first air flow pipe valve 93a and the second air flow pipe valve 93b are closed to prevent air from flowing into the chamber 11 through the first air flow pipe 91a and the second air flow pipe 91b. In the non-moving state, while moving the moving body 160 to the bottom of the chamber 11 while bringing the moving body 160 into close contact with the glass window surface, that is, scraping the glass window surface with the moving body 160 to force the remaining beads 1 attached to the glass window surface. It may be desorption.

Meanwhile, the plurality of beads 1 discharged from the chamber 11 and stored in the storage tank 50 are prevented from leaking to the air discharge pipe 85 by the storage bead blocking member 51 provided in the storage tank 50. .

In addition, the air introduced into the storage tank 50 together with the plurality of beads 1 passes through the storage bead blocking member 51 and passes through the air discharge pipe 85 and the communication pipe 95 to pass through the main blower 97. Through the outside.

After the plurality of beads 1 discharged from the chamber 11 are stored in the reservoir 50, the bead flow pipe valve 73, the bead discharge pipe valve 83, the air discharge pipe valve 87, and the beads that have been opened are stored. The return pipe valve 79b is closed, and the branch pipe valve 103 is closed at the same time.

Then, by stopping the operation of the main blower 97, the chamber 11 of the double window 10 is a state in which a plurality of beads 1 are discharged, it can be viewed through the double window (10).

Figure 22 shows a double glazing insulation system according to a fourth embodiment of the present invention.

As shown in the figure, unlike the first embodiment described above, the double glazing insulation system according to the fourth embodiment of the present invention does not include a movable body and a movable body moving unit, and includes a plurality of supports 190.

The support 190 is disposed at intervals in the chamber 11, and is fixedly supported on the pair of glass windows while maintaining a gap between the pair of glass windows.

In the present embodiment, a plurality of supports 190 may be provided, but at least one support 190 may be provided.

Thereby, the plurality of beads 1 accommodated in the chamber 11 between the pair of glass windows by the blowing of the main blower 97 are discharged to the storage tank 50, or the plurality of beads 1 stored in the storage tank 50. ) Is filled into the chamber 11, it is possible to reduce the breakage of the glass window by preventing the chamber 11 of the double window 10 is contracted by the support 190.

23 and 24 show a double glazing insulation system according to a fifth embodiment of the present invention in which the internal structure of the double glazing of the double glazing insulation system according to the first embodiment of the present invention is modified.

As shown in these figures, unlike the first embodiment described above, the double glazing 10 of the double glazing insulation system according to the fifth embodiment of the present invention has a plurality of moving bodies 160a, 160b, 160c having a chamber 11. It is possible to get on and off at. In addition, the chamber 11 is not provided with a chamber air inlet tube, and the chamber 11 is provided with a chamber bead blocking member 17 having a 'C' cross-sectional shape.

On the other hand, the plurality of moving body (160a, 160b, 160c) maintains the distance between the pair of glass windows, and has a form of a blind curtain to move up and down in the chamber (11) to access and space apart.

Each movable body 160a, 160b, 160c has a thickness corresponding to the distance between the pair of glass windows, and has a rectangular plate shape, as shown in FIG.

The rectangular opening 161 is formed in the center area | region and both ends of each movable body 160a, 160b, 160c so that the some bead 1 can move.

In the present embodiment, three movable bodies 160a, 160b, and 160c are disposed in the vertical direction of the chamber 11, but the number of movable bodies is not limited thereto, and one or more movable bodies may be provided.

These movable bodies 160a, 160b, 160c are lifted from the chamber 11 by the movable unit 170c.

The moving unit 170c includes a wire 171, a wire drum 173, and a drive motor 175 for a wire drum.

The wire 171 is penetrated and coupled to each of the movable bodies 160a, 160b, and 160c to suspend and support the movable bodies 160a, 160b, and 160c, and elevate the movable bodies 160. In this embodiment, each movable body 160a, 160b, 160c is suspended and supported by a pair of wires 171 in order to prevent the movable body from rocking during lifting. In addition, the movable bodies 160a, 160b, and 160c are connected to each other by a pair of auxiliary wires 172 at intervals.

The wire drum 173 has a cylindrical shape and is provided on the outer upper portion of the double glazing 10 to wind and unwind the wire 171.

The drive motor 175 for the wire drum is provided on the outer upper portion of the double window 10 to rotate the wire drum 173 forward and backward.

Accordingly, when the drive motor 175 for the wire drum is rotated in one direction, the wires 171 are wound around the wire drum 173 and the movable bodies 160a, 160b, and 160c are raised above the chamber 11. In addition, when the drive motor 175 for the wire drum is rotated in the other direction, the wires 171 are unwound from the wire drum 173 and the movable bodies 160a, 160b, 160c are lowered to the bottom of the chamber 11. do.

As such, by providing the plurality of movable bodies 160a, 160b, and 160c that move up and down in the chamber 11, the plurality of beads 1 are filled in the chamber 11 or the chamber 11 when being discharged from the chamber 11. With respect to the negative pressure generated in the), the plurality of moving bodies (160a, 160b, 160c) serves as a pillar for supporting a pair of glass windows, so that the shrinkage phenomenon does not occur in the chamber 11, the glass window is broken Can be reduced.

In addition, when the plurality of beads 1 are discharged from the chamber 11, each of the movable bodies 160a, 160b, and 160c descends toward the bottom region of the chamber 11, while remaining beads adhered to each window surface by electrostatic force. By forcibly detaching (1), the remaining beads (1) flow through the bead outlet (19) to the bead discharge pipe (81), and the glass window can be kept clean.

25 and 26 illustrate a double glazing insulation system according to a sixth embodiment of the present invention in which the internal structure of the double glazing of the double glazing insulation system according to the second embodiment of the present invention is modified.

As shown in these figures, the double glazing 10 of the double glazing insulation system according to the sixth embodiment of the present invention, unlike the second embodiment described above, a plurality of moving body (160a, 160b, 160c) is the chamber 11 It is provided to be movable from side to side. In addition, an air inlet 15 communicating with an air flow tube (not shown) is provided on the opposite side of the bead inlet 13 at the upper end of the chamber 11.

On the other hand, the plurality of moving body (160a, 160b, 160c) is to maintain the distance between the pair of glass windows, and move to the left and right of the chamber 11 has a form of a blind curtain to access and space apart.

Each movable body 160a, 160b, 160c has a thickness corresponding to the distance between the pair of glass windows, and has a rectangular plate shape, as shown in FIG.

The rectangular opening 161 is formed in the center area | region and both ends of each movable body 160a, 160b, 160c so that the some bead 1 can move.

In the present embodiment, three moving bodies (160a, 160b, 160c) are arranged in the left and right directions of the chamber 11, but the number of moving bodies is not limited to this, one or more may be provided.

These movable bodies 160a, 160b, and 160c move to the left and right of the chamber 11 by the movable unit 170d.

The movable body moving unit 170d includes a screw shaft 181 for the movable body and a screw shaft drive motor 183 for the movable body.

The moving screw shaft 181 is disposed above the chamber 11 with respect to the moving bodies 160a, 160b, and 160c. The screw shaft 181 for the movable body is screwed so as to be screwed with the movable body support 162 for supporting the movable bodies 160a, 160b, and 160c, and the movable body support 162 is a bead among the movable bodies 160a, 160b, and 160c. Suspendingly supports the movable body (160a) located closest to the inlet (13).

On the other hand, each of the moving body (160a, 160b, 160c) is connected to each other by a pair of auxiliary wires 172 to maintain the interval.

The screw shaft drive motor 183 for the mobile body is coupled to the screw shaft 181 for the mobile body, and rotates the screw shaft 181 for the mobile body forward and backward.

Accordingly, when the screw shaft drive motor 183 for the movable body is rotated in one direction, the movable bodies 160a, 160b and 160c move toward the bead inlet 13, and the movable bodies 160a, 160b and 160c are the auxiliary wires 172. Spaced apart by). In addition, when the screw shaft drive motor 183 for the movable body is rotated in the other direction, the movable bodies 160a, 160b, and 160c move to be spaced apart from the bead inlet 13, and the movable bodies 160a, 160b, and 160c access each other. do.

As such, by providing the plurality of moving bodies 160a, 160b, and 160c moving left and right in the chamber 11, the plurality of beads 1 are filled in the chamber 11, or the chamber is discharged from the chamber 11. With respect to the negative pressure generated in (11), the plurality of moving bodies (160a, 160b, 160c) acts as a pillar for supporting a pair of glass windows, so that the shrinkage phenomenon does not occur in the chamber (11), so that the glass window It can reduce the breakage.

In addition, when the plurality of beads 1 are discharged from the chamber 11, each of the moving body (160a, 160b, 160c) is moved toward the bead inlet 13, the remaining beads (1) attached by the electrostatic force to each glass window surface ), The remaining beads 1 flow through the bead outlet 19 to the bead discharge pipe 81, and keep the glass window clean.

In the above, embodiments of the present invention have been described with reference to the accompanying drawings, but those skilled in the art to which the present invention pertains may realize the present invention in other specific forms without changing the technical spirit or essential features thereof. I can understand that. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive.

1: Bead 10: Double Window
11: chamber 13: bead inlet
15 air outlet 17 bead blocking member for the chamber
19: Bead discharge port 30a, 30b, 30c, 30d: Bead discharge means
31: chamber air inlet pipe 35: air injection member
41: screw shaft 43: screw shaft drive motor
45: belt conveyor 50: reservoir
61 stirrer 71 bead flow tube
75: bead supply pipe 79a: bead recovery pipe
81: bead discharge pipe 85: air discharge pipe
91: air flow tube 95: communication tube
97: main blower 101: branch pipe
105: auxiliary blower 111: auxiliary air flow pipe
115: auxiliary bead discharge pipe 160: mobile body
170a, 170b, 170c, 170d: moving unit

Claims (19)

A chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, a bead outlet through which the plurality of beads and air received in the chamber are discharged, and air into the chamber A double glazing defining one or more air inlets and outlets;
A movable body provided to be movable in the chamber while maintaining a gap between the pair of glass windows;
A movable body moving unit which moves the movable body; And
A bead discharge means for discharging said plurality of beads contained in said chamber to said bead outlet;
The bead discharge means,
A chamber air inlet tube provided on the opposite side of the bead outlet to communicate with the chamber to introduce air into the chamber; And
It is formed by stacking a plurality of pipes of different lengths, and provided in the bottom of the chamber or the chamber air inlet pipe, including an air injection member for injecting air flowing along the chamber air inlet pipe toward the bead outlet, Double glazing insulation system. The method of claim 1,
The movable body is provided to be elevated in the chamber,
The mobile unit is,
A wire supporting the movable body and lifting and lowering the movable body;
A wire drum in which the wire is wound or unwound; And
And a drive motor for a wire drum for rotating said wire drum. The method of claim 1,
The movable body is provided in plural to be movable in the chamber,
The mobile unit is,
One or more wires suspending the plurality of movable bodies and lifting the plurality of movable bodies;
One or more auxiliary wires connecting the plurality of moving bodies to be spaced apart from each other;
A wire drum in which the wire is wound or unwound; And
And a drive motor for a wire drum for rotating said wire drum. The method of claim 1,
The movable body is provided to be accessible or spaced apart from the bead inlet,
The mobile unit is,
A screw shaft for a movable body provided horizontally with respect to the movable body and screwed to the movable body; And
And a screw shaft drive motor for a movable body for rotating the screw shaft for the movable body. The method of claim 1,
The movable body is provided in plural to be accessible or spaced from the bead inlet,
The mobile unit is,
One or more auxiliary wires connecting the plurality of moving bodies to be spaced apart from each other;
A screw shaft for a movable body provided horizontally with respect to the movable body and screwed to any one of the movable bodies; And
And a screw shaft drive motor for a movable body for rotating the screw shaft for the movable body. The method of claim 1,
The movable body is provided to be accessible or spaced apart from the bead inlet,
The mobile unit is,
A driving rod connected to the movable body; And
And an actuator for lengthening and lengthening the drive rod to linearly reciprocate the moving body. The method of claim 1,
And a guide provided along the moving direction of the movable body to guide the movement of the movable body. delete The method of claim 1,
The bead discharge means,
And a valve for a chamber air inlet tube provided in the chamber air inlet tube to open and close the chamber air inlet tube. delete A chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, a bead outlet through which the plurality of beads and air received in the chamber are discharged, and air into the chamber A double glazing defining one or more air inlets and outlets;
A movable body provided to be movable in the chamber while maintaining a gap between the pair of glass windows;
A movable body moving unit which moves the movable body; And
A bead discharge means for discharging said plurality of beads contained in said chamber to said bead outlet;
The bead discharge means,
A screw shaft having a spiral shape and rotatably provided at the bottom of the chamber toward the bead outlet; And
And a screw shaft drive motor for rotating said screw shaft. A chamber formed between a pair of glass windows, at least one bead inlet through which a plurality of beads and air are introduced into the chamber, a bead outlet through which the plurality of beads and air received in the chamber are discharged, and air into the chamber A double glazing defining one or more air inlets and outlets;
A movable body provided to be movable in the chamber while maintaining a gap between the pair of glass windows;
A movable body moving unit which moves the movable body; And
A bead discharge means for discharging said plurality of beads contained in said chamber to said bead outlet;
The bead discharge means,
And a belt conveyor provided at the bottom of the chamber and defining a caterpillar and discharging the plurality of beads contained in the chamber toward the bead outlet. The method of claim 1,
A reservoir for storing the plurality of beads; And
And a main blower for sucking or blowing air in the chamber to fill the chamber with the plurality of beads stored in the reservoir or to discharge the plurality of beads filled in the chamber to the reservoir. Insulation system. The method of claim 13,
A bead flow tube connected to the reservoir to guide the plurality of beads to flow;
A bead supply pipe branched from the bead flow pipe and connected to the bead inlet;
A bead discharge pipe branched from the bead flow pipe and connected to the bead discharge port;
An air discharge pipe connected to the reservoir for guiding the flow of air discharged from the reservoir;
An air flow pipe connected to the air inlet and guiding a flow of air to and from the air inlet; And
And a communication tube communicating with the air flow pipe and the air discharge pipe, wherein the main blower is provided. The method of claim 14,
A branch pipe branched from the air flow pipe to guide the flow of air;
A branch pipe valve provided in the branch pipe to open and close the branch pipe; And
And a supplementary blower provided in the branch pipe and configured to press-fit and blow air into the chamber through the branch pipe and the air flow pipe. The method of claim 15,
Wherein said chamber air inlet pipe branches from said air flow pipe or said branch pipe. The method of claim 14,
A bead flow pipe valve provided in the bead flow pipe to open and close the bead flow pipe;
A bead supply pipe valve provided in the bead supply pipe to open and close the bead supply pipe;
A bead discharge pipe valve provided in the bead discharge pipe to open and close the bead discharge pipe;
An air discharge pipe valve provided in the air discharge pipe to open and close the air discharge pipe; And
It is provided in the air flow pipe, and includes an air flow valve for opening and closing the air flow pipe,
When the plurality of beads are filled from the reservoir to the chamber, the bead flow pipe valve and the bead supply pipe valve are opened, the bead discharge pipe valve is closed, and the plurality of beads are discharged from the chamber to the reservoir. And wherein the valve for the bead flow line and the valve for the bead discharge line are open and the valve for the bead feed line is closed. The method of claim 17,
A bead recovery pipe branched from the bead supply pipe or the bead flow pipe and connected to the reservoir; And
A bead recovery pipe valve provided in the bead recovery pipe to open and close the bead recovery pipe;
The bead recovery tube valve is closed when the plurality of beads are filled from the reservoir to the chamber, and the bead recovery tube valve is opened when the plurality of beads are discharged from the chamber to the reservoir. delete

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