KR20210058507A - sliding window - Google Patents

Abstract

According to the present invention, a flow prevention type horizontal sliding window having an improved restoration structure comprises a sash assembly, a window assembly, and a spring member. In particular, the spring member is configured to maintain a state in contact with the wall surfaces of both sides of a guide rail even though the window assembly is in an open state, and, at the same time, assist the release of restraints allowing the window assembly to be easily opened, while being maintained in a compressed state when the window assembly is closed, and restored when the window assembly is opened.

Description

Flow-proof sliding window with improved restoration structure {sliding window}

The present invention relates to the window of the secretary, and more specifically, the window assembly can be maintained in a stable installation state even when vibrations such as drafts or earthquakes occur, and the restraint is quickly released from the guide rail of the window frame frame during the opening operation. The present invention relates to a flow-preventing type window with an improved restoration structure in which the window assembly can be opened easily and is not deformed or damaged even if it is used for a long period of time.

In general, a window is a structure including a chassis assembly that is embedded in a building wall and a window assembly that is installed to be slidably movable in the chassis assembly and selectively opens and closes an open portion of the chassis assembly.

The window assembly of such a window includes a window and a window frame on which the window is mounted, and is installed to be slidably moved to the chassis assembly to selectively block or open indoors and outdoors.

The above-described windows are mainly used as sliding doors for opening and closing windows in a sliding structure, and these sliding windows are usually installed to open and close the chassis assembly in a sliding manner while forming a pair of two window assemblies.

At this time, guide rails are formed to protrude from opposite surfaces of the two horizontal window frame frames constituting the chassis assembly, so that the two window assemblies are guided by the guide rails to perform accurate sliding movement.

On the other hand, for the operability of each window assembly, the two window assemblies slide apart from each other when the window is opened, and when the window is closed, the two window assemblies are adjacent to each other. It is configured to prevent the outside air from entering or the indoor air from flowing out between the gaps or between the gaps between the two window assemblies.

Regarding this, it is as disclosed in Utility Model Registration No. 20-0183492, Utility Model Registration No. 20-0201605, Utility Model Registration No. 20-0362211, and Utility Model Registration No. 20-0362227.

In this case, a foreign material blocking member such as a non-woven fabric, velvet, gasket or brush is provided between the gap between the chassis assembly and the window assembly or between the two window assemblies to prevent the introduction of foreign materials.

However, the above-described conventional techniques have a disadvantage in that when the foreign material blocking member is excessively in close contact with the window assembly, the operability of each window assembly is deteriorated, and thus the adhesion cannot be improved and the sealing property is inevitably deteriorated.

In addition, a structure such as a brush structure or a nonwoven fabric can sufficiently secure the operability of the window assembly, but has a disadvantage in that the sealing property is extremely low as air passes between the brushes.

In particular, when the window assembly is in the open state, the center of the guide rail and the center of the window assembly do not coincide with each other and form a misaligned state. There was a problem that there is a concern about the damage of the.

Of course, recently, a technique for preventing the above-described conventional problem has been provided, as disclosed in Korean Patent No. 10-1799543.

That is, by installing restoring anti-shake parts on both sides of the guide rail in the rail accommodating part of the window frame, flow is prevented during normal times, and sealing properties are secured by using the restoring force when opening and closing the window.

However, in the case of the above-described technology, there is a concern that the restoring force of the restoring anti-shake unit formed of a restorable material may not be prevented due to a phenomenon in which the restoring force is deteriorated due to long use or the influence of external environments.

Registered Utility Model Publication No. 20-0183492 Registered Utility Model Publication No. 20-0201605 Registered Utility Model Publication No. 20-0362211 Registered Utility Model Publication No. 20-0362227

The present invention was conceived to solve various problems of the prior art described above, and an object of the present invention is to ensure that the window assembly can be maintained in a stable installation state even when vibrations such as drafts or earthquakes occur, and the window frame is opened during operation. It is to provide a flow-preventing type window with an improved restoration structure in which the opening operation of the window assembly is easily performed by returning to be quickly released from the guide rail of the frame.

The flow-prevention type sliding door window having an improved restoration structure of the present invention for achieving the above object includes: a window frame frame in which a guide rail is protruded; A window frame that is slidably moved by the guide rail while the rail receiving portion accommodating the guide rail is concavely formed; And a spring member positioned within the rail receiving portion of the window frame, maintaining a state in close contact with the guide rail, and providing a restoring force to assist release of the restraint while being restored when the window frame is opened. .

Here, the spring member has a fixing part fixed to an upper wall surface in the rail receiving part, and a side surface formed to extend downward from both sides of the fixing part, and partially bent so as to contact each side wall surface of the guide rail. It characterized in that it is configured to include a close contact.

In addition, the fixing part of the spring member is formed in a flat shape and is in close contact with the upper wall surface in the rail receiving part, and two guide protrusions are formed respectively protruding on the upper wall surface in the rail receiving part, and the fixing part is positioned between the two guide protrusions. It is characterized in that it is configured to be.

In addition, the side contact portion is characterized in that it is formed to repeat the irregularities while being bent in a round shape.

In addition, a mounting groove is formed in the interior wall surface and the outdoor wall surface in the rail accommodating portion constituting the window frame, and the spring member is accommodated and installed in the mounting groove, and the spring member protrudes from the mounting groove by the spring member. A contact member is provided in close contact with the side wall of the rail, and the spring member is formed of a coil-type spring.

As described above, the flow-preventing sliding window having an improved restoration structure of the present invention is in a state in which the spring member is in contact with the wall surfaces of both sides of the guide rail even in the open state by the additional provision of the spring member. It has the effect of preventing non-vibration.

In addition, even though the window assembly is open, the window assembly is prevented from shaking by the spring member even though the window assembly is in an open state, the window assembly is prevented from shaking. It has the effect of preventing the damage of the window assembly or the detachment of the window assembly from the chassis assembly.

In addition, the flow-prevention type sliding door window having the improved restoration structure of the present invention is restored when the spring member is opened when each window assembly is opened, and as a result of assisting the release of the restraint of the window assembly, a more smooth opening operation can be performed. Has an effect.

In addition, the flow-prevention type window and door having an improved restoration structure of the present invention has the effect that the spring member is formed of metal or plastic material, so that even if it is used for a long period of time, it is possible to perform accurate operation without causing deformation or damage. Have.

1 is a state diagram showing to explain the appearance of a flow-preventing secretary window having an improved restoration structure according to an embodiment of the present invention
FIG. 2 is a cross-sectional view taken along the line I-I of FIG. 1 for explaining a state when a door is closed of a flow-preventing secretary window having an improved restoration structure according to an exemplary embodiment of the present invention.
FIG. 3 is a cross-sectional view taken along line II-II of FIG. 1 for explaining a state when a door is closed of a flow-preventing secretary window having an improved restoration structure according to an exemplary embodiment of the present invention.
FIG. 4 is an enlarged view of part “A” of FIG. 3
Figure 5 is a perspective view showing to explain the spring member of the flow-prevention type secretary window having an improved restoration structure according to an embodiment of the present invention
FIG. 6 is a view of the window assembly viewed from the bottom to explain the installation state of the spring member of the flow-preventing sliding window having an improved restoration structure according to an embodiment of the present invention;
7 is a cross-sectional view illustrating a state when a door is opened of a flow-preventing secretary window having an improved restoration structure according to an embodiment of the present invention.
FIG. 8 is a longitudinal sectional view showing a state when a door is opened of a flow-preventing secretary window having an improved restoration structure according to an embodiment of the present invention;
9 is an enlarged view of the “B” part of FIG. 8
10 and 11 are state diagrams for each operation shown to explain another embodiment of a spring member of a flow-prevention type window and door having an improved restoration structure according to an embodiment of the present invention;

Hereinafter, a preferred embodiment of the flow-preventing non-secretary window having an improved restoration structure of the present invention will be described with reference to FIGS. 1 to 11.

1 is a state diagram showing the appearance of a flow-preventing secretary window having an improved restoration structure according to an embodiment of the present invention, and FIG. 2 is a diagram having an improved restoration structure according to an embodiment of the present invention. 1 is a cross-sectional view taken along the line Ⅰ-Ⅰ of FIG. 1 to explain the state of the flow-preventing non-secretary window when the door is closed, and FIG. 3 is a flow-prevention type non-secretary window door having an improved restoration structure 1 is a cross-sectional view taken along the line II-II of FIG. 1 for explaining the closed state.

As shown in these drawings, the flow-preventing sliding door window having an improved restoration structure according to an embodiment of the present invention largely includes a chassis assembly 100, a window assembly 201, 202, and a spring member 300. . In particular, the spring member 300 maintains a state in contact with both side walls of the guide rail 121 even though the window assembly is in an open state. In addition, when the window assemblies 201 and 202 are closed, the spring member 300 is in a compressed state. It is suggested that the window assemblies 201 and 202 are restored when the window assemblies 201 and 202 are opened while being maintained and configured to assist release of the constraint so that the corresponding window assemblies 201 and 202 are easily opened.

This will be described in more detail for each configuration.

First, the chassis assembly 100 will be described.

The chassis assembly 100 is a structure in which window assemblies 201 and 202, which will be described later, are installed to be slidably movable while forming a skeleton of a window of the secretary.

The chassis assembly 100 is formed by combining two vertical side window frame frames 110 provided in a vertically erected state and two horizontal side window frame frames 120 provided in a horizontally laid state in a rectangular frame structure.

Here, a pair of accommodating protrusions 111 are formed to protrude on opposite surfaces between the two vertical window frame frames 110, and a pair of guide rails 121 are formed on opposite surfaces between the two horizontal window frame frames 120 It is formed by protruding.

In addition, partitions 112 and 122 are formed to protrude between each of the guide rails 121 and between the receiving protrusions 111 among the facing surfaces between the window frame frames 110 and 120, respectively.

The partitions 112 and 122 prevent inclination and unwanted separation of the two window assemblies 201 and 202 and block the inflow of outside air through the gap between the chassis assembly 100 and each of the window assemblies 201 and 202. It is a configuration provided to perform.

That is, the interior of the chassis assembly 100 is divided into an indoor side and an outdoor side due to the partitions 112 and 122 described above. At this time, the partitions 112 and 122 may be formed of an insulating material such as polyimide, and are coupled to the vertical partition 112 and the horizontal window frame 120 coupled to the vertical window frame 110 It is divided into a horizontal partition portion (122).

Airtight members 113 and 123 are provided on both wall surfaces of the partitions 112 and 122 to maintain airtightness while being in close contact with both wall surfaces of the window assemblies 201 and 202 when the window assemblies 201 and 202 are moved adjacently.

Next, the window assemblies 201 and 202 will be described.

The window assemblies 201 and 202 are structures that are installed in the indoor and outdoor installation areas provided by the chassis assembly 100 and divide indoor and outdoor windows into transparent windows.

Such window assemblies 201 and 202 include an indoor window assembly 201 located on an indoor side and an outdoor window assembly 202 located on an outdoor side, and these two window assemblies 201 and 202 include the chassis assembly 100 ) Is installed to be slidably movable under the guidance of the guide rails 121 of the two horizontal window frame frames 120 forming a ).

Meanwhile, the two window assemblies 201 and 202 each include a window 210 and a window frame 220 supporting the window 210.

Here, the window frame 220 is formed in a rectangular frame structure surrounding the circumference of the window 210.

In addition, in the upper and lower surfaces of each of the circumferential surfaces of the window frame 220 opposite to the two horizontal window frame 120, a rail receiving portion 221 for accommodating the guide rail 121 is concavely formed, and the window frame Protrusion receiving portions 222 for accommodating the receiving protrusions 111 are formed on the front and rear surfaces of each of the circumferential surfaces of 220 opposite to the two vertical window frame 110. In this case, a roller 223 mounted on the upper surface of the guide rail 121 on the lower side of the rail receiving portion 221 located at the lower side of the two rail receiving portions 221 of the window frame 220 is provided.

In addition, mounting grooves 231 and 241 are formed on both side walls (surfaces opposite to both side walls of the guide rail) in the rail receiving unit 221 located at the lower side of the two rail receiving units 221 of the window frame 220. Mounting portions 230 and 240 are formed to protrude.

At this time, the mounting portions 230 and 240 are provided as a portion for pressing a spring member to be described later, and these mounting portions 230 and 240 are an indoor mounting portion 230 positioned on the interior side when viewed from the position of the guide rail 121 Wow, it is provided with an outdoor-side mounting part 240 located on the outdoor side.

Seal members 250 may be installed in the mounting grooves 231 and 241 of the mounting portions 230 and 240 provided on both side walls of the rail receiving portion 221.

This seal member 250 is maintained in contact with the wall surface of the guide rail 121 when the window assemblies 201 and 202 are closed, and outdoor air is introduced into the room through the gap generated between the guide rail 121 and the guide rail 121. It serves to prevent, and is preferably formed of a material that can be compressed and restored, such as rubber or sponge.

Of course, in the case of the seal member 250 located indoors, compression is not required, and thus may be composed of a conventional brush, or may be composed of a block body that is in close contact with the wall surface of the guide rail 121.

In addition, a pressing member 224 is provided in the protrusion receiving portion 222 of the window frame 220, respectively. At this time, when the window assemblies 201 and 202 are closed, the pressing member 224 forcibly moves the two window assemblies 201 and 202 to be adjacent in opposite directions between the three rolls by gradual contact with the receiving protrusion 111.

Next, the spring member 300 will be described with reference to FIGS. 4 to 6.

The spring member 300 maintains a state in close contact with the guide rail 121 and provides a restoring force when the window frame 220 is opened, while reducing the pressing force between the pressing member 224 and the receiving protrusion 111 to be easily restrained. It plays a role of assisting to release.

The spring member 300 is located within the rail receiving portion 221 of the window frame 220. In particular, the spring member 300 is provided only at a portion of the front side (closed direction side) in the rail receiving portion 221 so as to act only when the window assembly is closed or opened. At this time, the seal member 250 does not exist in the portion where the spring member 300 is positioned so as to prevent interference with each other.

Such a spring member 300 is made of a plate spring made of a metal material, and includes a fixing portion 310 and two side contact portions 321 and 322.

Here, the fixing part 310 is a part fixed to the upper wall surface in the rail receiving part 221 constituting the window frame 220.

This fixing part 310 is formed in a flat plate shape and is installed in close contact with the upper wall surface in the rail receiving part 221, and is preferably fixed by fastening a screw for a more robust installation.

In particular, two guide protrusions 221a are formed to protrude to be spaced apart from each other on the upper wall surface in the rail receiving part 221, and the fixing part 310 is in close contact with a portion provided between the two guide protrusions 221a. It is made to be fixed in the state.

In addition, the side contact portions 321 and 322 are formed to extend downward from both sides of the fixing portion 310, respectively.

In particular, the side contact portions 321 and 322 are formed in a concave-convex structure that repeats protrusion and concaveness inward (in the direction of the opposite surface between the two side contact portions) or outward.

The protruding and concave portions of the side contact portions 321 and 322 are formed to be repeated while forming a round structure, so that compression deformation and restoration deformation can be smoothly performed.

In addition, the lower end portions of the side contact portions 321 and 322 are formed to protrude inward so as to be in close contact with the opposite side wall of the guide rail 121, and the lower end is formed to gradually move away from the guide rail 121.

That is, the two side contact portions 321 and 322 are maintained in contact with each side wall of the guide rail 121, and when a closing operation of the corresponding window assembly 201 and 202 occurs, one of the two side contact portions 321 and 322 The side contact portion 321 on the outdoor side is compressed and deformed in a state in close contact with the wall surface of the guide rail 121, and provides a restoring force when the opening operation of the window assemblies 201 and 202 occurs again. The sealing members 113 and 123 are quickly separated from the outer wall surface of the window frame 220 and the seal member 250 of the corresponding window assembly 201 and 202 is rapidly separated from the guide rail 121 (or pressurized), so that the sliding movement is performed. It serves to assist in making it work smoothly.

The spring member 300 may be formed of a metal material or a synthetic resin material such as plastic.

In the following, the operation state of the flow-prevention type secretary window having an improved restoration structure according to the embodiment of the present invention described above will be described in more detail.

First, the attached FIGS. 2 to 4 show an indoor window assembly 201 and an outdoor window assembly 202 of a window of a non-surgeon according to an embodiment of the present invention in a closed state.

As described above, when the two window assemblies 201 and 202 are closed, the pressing member 224 provided in the protrusion receiving portion 222 of the two window assemblies 201 and 202 contacts each of the window assemblies 201 and 202 by contact with the receiving protrusion 111. Is in a state of being forced to move adjacent to each other in the opposite direction, and in the case of the spring member 300, one of the two side contacting parts 321 and 322 (in the case of an outdoor window assembly, it is an outdoor side contacting part, indoors In the case of the side window assembly, the indoor side side contact portion) is compressed and deformed in a state in which each guide rail 121 is in close contact with each other.

In addition, each of the window assemblies 201 and 202 maintains airtightness while being in close contact with the airtight members 113 and 123 provided on the walls of the partitions 112 and 122.

As a result, inflow of outside air through the gap between the outdoor window assembly 201 and the chassis assembly 100 is prevented by the airtight members 113 and 123, while the window assemblies 201 and 202 remain stable while maintaining a stable fixed state. This can be prevented.

Meanwhile, when the two window assemblies 201 and 202 are slid and opened according to the needs of the user in the closed state of each of the window assemblies 201 and 202 as described above, the pressing member 224 provided in the protrusion receiving portion 222 is a chassis assembly. It is separated from the receiving protrusion 111 of (100).

Accordingly, the indoor window assembly 201 and the outdoor window assembly 202 are separated from the partitions 112 and 122 by the restoring force of the airtight members 113 and 123.

In addition, the side contact part forming the spring member 300 (the outdoor side contact part in the case of the outdoor window assembly, and the indoor side contact part in the case of the indoor window assembly) is also restored due to release of the pressing force by the opening operation. The restraint to the guide rail 121 is released. This is as shown in the accompanying Figures 7 to 9.

In particular, as the side contact portions 321 and 322 of the spring member 300 are formed to be rounded while forming an uneven structure in which mountains and valleys are repeated, when the compression force is released, the side contact portions 321 and 322 are rapidly restored and each window assembly ( As the restraint release of the 201 and 202 is assisted, the restraint is released together with the opening operation of the window assemblies 201 and 202, and the window assemblies 201 and 202 can be easily opened while sliding.

In addition, when the spring member 300 is completely restored, the two side contact portions 321 and 322 are in contact with both side walls of the guide rail 121 at the same time.

As described above, when the window assemblies 201 and 202 are open, the two side contact portions 321 and 322 of the spring member 300 are kept in contact with both walls of the guide rail 121 at the same time. Shaking of the corresponding window assemblies 201 and 202 may be prevented.

Moreover, since the two side contact portions 321 and 322 are not in close contact with each other while being pressed against the walls of both sides of the guide rail 121, the friction force with the guide rail 121 is practically small, and thus the user's operation Accordingly, the sliding movement of the window assemblies 201 and 202 may be performed smoothly.

As a result, the flow-prevention type sliding window having an improved restoration structure of the present invention is in a state in which the spring member 300 is in contact with the wall surfaces of both sides of the guide rail 121 even in the open state by the additional provision of the spring member 300. This prevents unwanted shaking of the window assemblies 201 and 202.

Accordingly, glass breakage caused by shaking of the window assemblies 201 and 202 due to the influence of wind or earthquake, or separation of the window assemblies 201 and 202 are prevented.

In particular, the flow-preventing sliding window having an improved restoration structure of the present invention is more smooth by assisting the release of the restraints of the window assemblies 201 and 202 while the spring member 300 is restored when the respective window assemblies 201 and 202 are opened. It becomes possible to perform the open operation.

On the other hand, the spring member 300 constituting the flow-prevention type window and door having the improved restoration structure of the present invention is not limited to being implemented only in the shape of the above-described embodiment.

For example, as shown in the accompanying Figures 10 and 11, the spring member 300 is an outdoor mounting groove 241 among two mounting grooves 231 and 241 formed in the rail receiving portion 221 of the outdoor window assembly 202 It may be configured to be installed in.

In this case, the spring member 300 is elastically protruded from the mounting groove 231 by the spring 331 installed in the mounting groove 231 and the spring 331 to the side of the guide rail 121 It is configured to include a close contact portion 332 in close contact with the wall surface. In this case, the spring 331 may be formed of a coil-type spring.

In addition, a support member 400 made of an incompressible material may be installed in the indoor mounting groove 241.

At this time, the spring 331 is made of a coil-type spring, the contact portion 332 is formed in a cap structure in which the end of the spring 331 is accommodated, and its outer surface (the side opposite to the guide rail) Face) is formed to be round.

That is, when the window assemblies 201 and 202 are closed, the contact portion 332 is pressed against the guide rail 121 and contacts the guide rail 121 while compressing the spring 331, and the window assemblies 201 and 202 During the opening operation, the contact portion 332 may be kept in contact with the guide rail 121 by the restoration operation of the spring 331.

Moreover, since the flow-preventing sliding window window having an improved restoration structure of the present invention is formed of a metal or plastic material, the spring member 300 is not deformed or damaged even if used for a long period of time and can perform an accurate operation. There will be.

As described above, the flow-preventing non-seogi window having an improved restoration structure of the present invention can be said to be a useful invention that not only can be modified in various ways, but also can be easily applied to the existing non-seogi window.

100. Chassis assembly 110. Vertical side window frame
111. Reception protrusion 112,122. Division
113,123. Airtight member 120. Horizontal window frame frame
121. Guide rail 201,202. Window assembly
210. Window 220. Window Frame
221. Rail receiving part 221a. Guide protrusion
222. Protrusion receiving part 223. Roller
224. Pressurizing member 230,240. Mounting part
231,241. Mounting groove 250., seal member
300. Spring member 310. Fixing part
321,322. Side contact 331. Spring
332. Adhesion part 400. Support member

Claims (5)

A window frame frame in which a guide rail is protruded;
A window frame that is slidably moved by the guide rail while the rail receiving portion accommodating the guide rail is concavely formed;
And a spring member positioned within the rail receiving portion of the window frame, maintaining a state in close contact with the guide rail, and providing a restoring force to assist release of the restraint while being restored when the window frame is opened. Flow-prevention type window with an improved restoration structure. The method of claim 1,
The spring member
A fixing part fixed to the upper wall surface in the rail receiving part,
A flow prevention type miscellaneous device having an improved restoration structure, characterized in that it is formed to extend downwardly from both sides of the fixing part, and part of it includes side contact parts bent so as to contact each side wall surface of the guide rail. Windows. The method of claim 2,
The fixing portion of the spring member is formed in a flat plate shape and is in close contact with the upper wall surface in the rail receiving portion,
A flow-prevention type non-secretary window having an improved restoration structure, characterized in that, while two guide protrusions are formed respectively protruding on the upper wall surface in the rail receiving part, the fixing part is positioned between the two guide protrusions. The method of claim 2,
The side contact portion is formed to repeat the irregularities while being bent in a rounded flow prevention type window with an improved restoration structure. The method of claim 1,
Mounting grooves are formed in recesses on the indoor wall and the outdoor wall in the rail accommodating part forming the window frame,
The spring member
A spring installed in the mounting groove on the outdoor wall among the respective mounting grooves,
A flow-preventing type window door having an improved restoration structure, characterized in that it comprises a contact portion that is elastically protruded from the mounting groove by the spring and is in close contact with the side wall surface of the guide rail.

Images