KR20220015698A - Touch-lever type lift slinging device - Google Patents

Abstract

A lift sliding device is disclosed. The lift sliding device of the present invention includes a support member to which a roller rolling along a rail of a window frame is rotatably coupled; The window is coupled, the body forming a first inclined surface; a first shaft member provided on the support member and supporting the first inclined surface; a first linker rotatably coupled to the first shaft member; and a locking jaw provided on the window frame, and when the window is pushed to open, the body is raised by the first inclined surface while the first linker is caught on the locking jaw. According to the present invention, it is possible to provide a lift sliding device that forms a simple structure and opens the window while pulling the window by rotating the handle within 45 degrees in the locked state.

Description

Touch-Lever Type Lift Sliding Device {TOUCH-LEVER TYPE LIFT SLINGING DEVICE}

The present invention relates to a touch-lever type lift sliding device, and more particularly, to a touch-lever type lift sliding device configured to elevate a window or a door when the sliding type windows are opened and closed.

In general, windows and doors are used as generic names for windows and doors in buildings, and the frame in which the windows are installed is called a window frame. Among these windows, sliding doors, which are mainly used for veranda doors and other windows, are sliding doors that can be opened and closed by sliding the window along the guide rail by installing a window equipped with a roller on a window frame equipped with a guide rail, soundproofing, multi-row, etc. There is a system window with a lift sliding system that further improved it.

In particular, in the case of a lift sliding system window, when the handle is rotated to open the window, the window sill is lifted from the rail a certain distance and opened quietly and smoothly. And in the closed state, it is formed to ensure airtightness, heat insulation, soundproofing and watertightness by being in close contact with the window. Lift sliding system windows are used for relatively large windows such as living room dividers and balcony windows.

In this regard, Republic of Korea Patent Publication No. 753571 (hereinafter 'prior literature') discloses a system window opening and closing device. The system window opening and closing device of the prior literature is configured to include a sliding lift unit and a lift operation unit.

The sliding lift unit is provided at the lower part of the window frame to support the window frame in sliding movement with respect to the window frame rail and spaced apart and closely in the vertical direction. The lift operation unit operates the sliding lift unit according to the opening/closing operation of a handle installed on one side of the window frame.

The lift operation unit is installed on the side of the window frame facing the window frame so as to be movable up and down and includes a lift operation bar for vertically operating the sliding lift unit, a locking protrusion member coupled to an inner portion of the window frame opposite to the lift operation bar, and a side portion of the window frame It is installed and includes a lift operation gear portion for operating the lift operation bar in the vertical direction according to the opening and closing operation of the handle, and a locking operation portion for locking and unlocking the upward movement of the lift operation bar.

The sliding lift unit is configured to include a roller part in rolling contact with the window frame rail, and a window frame support member coupled to the lower part of the window frame to vertically spaced apart and approach the roller unit.

A lift link is rotatably coupled to the front end of the roller support plate of the roller provided in front of the lower end of the window frame. The front end of the lift link is rotatably coupled to the lift hinge. The lower end of the lift connecting arm is rotatably coupled to the lift hinge. The lift connecting arm has an upper end connected to a lower end of a lift action bar, which will be described later.

When the user rotates the handle in the window frame opening direction to open the window frame, the lift operation bar moves upward according to the operation of the lift operation gear unit connected to the handle.

When the lift action bar acts upward, the lift connection arm rotates the lift hinge from the lower part of the window frame to the side, and the lift link pulls the roller part by the rotation of the lift hinge. Accordingly, the rail contact portion of the window frame supporting member is spaced apart from the window frame rail, and the window frame can be opened.

When the user wants to fix the window frame, if the user presses the locking operation switch of the locking operation part, the stopper stopper is rotated to the unlocking position and the locking state of the stopper is released.

At this time, the window frame support member approaches the roller unit while the lift action bar moves downward by the weight of the window frame. The rail contact portion of the window frame support member prevents the sliding movement of the window frame by pressing the rail downward by the weight of the window frame while in contact with the window frame rail. Accordingly, the position of the window frame is fixed.

However, the system window opening and closing device of the prior literature is inconvenient to open the window only by rotating the handle. People with low motor skills, such as the elderly or young children, may have difficulty in rotating the handle. In addition, the lift sliding system windows, which can be opened only by rotating the handle, can act as a factor to delay the escape speed when a similar situation occurs, such as when an indoor fire occurs. Therefore, the installation rate of lift sliding system windows is not high in facilities related to the elderly or children, such as nursing homes and kindergartens.

In addition, in the system window opening and closing device of the prior document, the rotational force of the handle is transmitted to the lift hinge through the lift operation gear unit, the lift operation bar and the lift connection arm whenever the window is opened. Devices that move heavy objects such as system windows have a high degree of wear of parts during operation. The wear of parts is directly related to the life of the device. Therefore, it has been required to simplify the structure of the touch-lever type lift sliding device.

Republic of Korea Patent Publication No. 753571 (Registration date: August 23, 2007)

It is an object of the present invention to provide a touch-lever lift sliding device which forms a simple structure and opens while pulling a window sill by rotating a handle within 45 degrees in a locked state.

The above object, according to the present invention, a support member to which the roller rolling along the rail of the window frame is rotatably coupled; The window is coupled, the body forming a first inclined surface; a first shaft member provided on the support member and supporting the first inclined surface; a first linker rotatably coupled to the first shaft member; and a clasp provided on the window frame, and when the window is pushed to be opened, the body is raised by the first inclined surface while the first linker is caught on the clasp. do.

The locking protrusion forms a first slope surface in contact with the first linker, the body forms a first interface surface at the lower end of the first inclined surface, and when the window is opened, the first shaft member is the first A When caught on the interface, the first linker may be rotated by the first inclined surface to come off the locking jaw.

a second linker rotatably coupled to the body and forming a link hole; a third shaft member provided in the first linker and inserted into the link hole; And when the window is opened, it may be made to include an intermittent unit for blocking the lowering of the body by the first inclined surface.

The locking protrusion forms a slope surface in contact with the first linker, the body forms a 1A interface at the lower end of the first inclined surface, and when the first shaft member is caught on the 1A interface, the first linker The link hole may be formed to have an elongated shape along the circumferential direction with respect to the first shaft member so as to rotate by the inclined surface.

The slope may include a first slope to which the first linker contacts when the window is opened; and a second slope that is in contact with the first linker when the window is closed, and is connected to the first slope at an upper end, wherein the first slope forms a steeper slope than the second slope.

The intermittent unit may include a push member coupled to the window frame; and an intermittent unit provided on the body, wherein the intermittent unit includes: a rack member pushed by the push member when the window is closed; a first elastic member for pushing the rack member toward the push member; a gear rotating by the rack member; And to selectively prevent rotation of the second linker, it may be made to include a latch that moves in engagement with the gear.

The intermittent unit may include a second elastic member interposed between the rack member and the latch to push the latch toward preventing rotation of the second linker.

The body may form a second inclined surface, and the support member may include a second shaft member supporting the second inclined surface.

According to the present invention, when the window is pushed to be opened, the body rises by the first inclined surface while the first linker is caught on the locking jaw, thereby forming a simple structure, and holding the window by rotating the handle within 45 degrees while the window is locked. It is possible to provide a touch-lever type lift sliding device that is opened while pulling.

1 is a view showing an installation state of a touch-lever type lift and sliding device according to an embodiment of the present invention.
2 is a perspective view of the touch-lever type lift sliding device of FIG. 1 .
3 is a partially exploded perspective view of the touch-lever type lift sliding device of FIG. 1 .
FIG. 4 is a view showing the use state of the touch-lever type lift and sliding device of FIG. 1, and is a cross-sectional view illustrating a state in which a push member and a rack member are spaced apart from each other.
FIG. 5 is a view showing the use state of the touch-lever type lift sliding device of FIG. 1, and is a cross-sectional view showing a state in which the locking member is positioned on the upper end of the locking jaw.
6 is a view showing the use state of the touch-lever type lift and sliding device of FIG. 1, and is a cross-sectional view showing a state in which the push member is pressing the rack member.
FIG. 7 is a view showing the use state of the touch-lever type lift and sliding device of FIG. 1 , and is a cross-sectional view showing a state in which the body is lowered.
Fig. 8 is a view showing the use state of the touch-lever type lift sliding device of Fig. 1, and is a cross-sectional view showing the state in which the body is raised.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted in order to clarify the gist of the present invention.

The touch-lever type lift sliding device of the present invention forms a simple structure and rotates the handle within 45 degrees in a locked state to open the window while pulling it.

1 is a view showing an installation state of a touch-lever type lift and sliding device 10 according to an embodiment of the present invention. FIG. 2 is a perspective view of the touch-lever type lift sliding device 10 of FIG. 1 .

3 is a partially exploded perspective view of the touch-lever type lift and sliding device 10 of FIG. 1 . 4 is a view showing the use state of the touch-lever type lift and sliding device 10 of FIG. 1 , and is a cross-sectional view showing a state in which the push member 920 and the rack member 911 are spaced apart from each other.

FIG. 5 is a view showing the use state of the touch-lever type lift and sliding device 10 of FIG. 1 , and is a cross-sectional view showing a state in which the engaging member 610 is positioned on the upper end of the engaging projection 800 . 6 is a view showing a use state of the touch-lever type lift and sliding device 10 of FIG. 1 , and is a cross-sectional view showing a state in which the push member 920 is pressing the rack member 911 .

7 is a view showing a use state of the touch-lever type lift and sliding device 10 of FIG. 1 , and is a cross-sectional view showing a state in which the body 200 is lowered. FIG. 8 is a view showing the use state of the touch-lever type lift and sliding device 10 of FIG. 1 , and is a cross-sectional view showing a state in which the body 200 is raised.

The sliding-type windows (1) shown by dotted and dashed lines in FIG. 1 shows sliding doors mainly used for veranda doors or other windows.

The window 1 is configured to include a window 2 (sash part) and a window frame 3 (frame part). 1 shows a lower sill and a side jamb of the window frame 3 . The window 2 includes a glass 2A and a window sill 2B. 1 shows the bottom and the side part (style) of the window (2B).

A Cartesian coordinate system is shown in FIGS. 1 to 8 . Hereinafter, a rectangular coordinate system will be used to describe the direction for easy understanding of the present invention.

The X direction may mean a longitudinal direction of the rail 3A. It moves in the longitudinal direction of the rail 3A of the window 2 . The Z direction may mean upward. The Y direction may mean a horizontal direction perpendicular to the X direction. Hereinafter, the horizontal direction may mean a ±X direction.

1 to 4, the touch-lever type lift sliding device 10 according to an embodiment of the present invention raises and lowers the window 2 or the door when the sliding type window 1 is opened and closed. and a support member 100, a body 200, a first shaft member 300, a second shaft member 400, a third shaft member 500, a first linker 600, a second linker ( 700), and is configured to include a locking jaw 800 and an intermittent unit 900.

As shown in Figures 2 and 3, the support member 100 has a configuration in which the roller 130 rolling along the rail 3A of the window frame 3 is rotatably coupled.

The support member 100 may include a first support plate 110 and a second support plate 120 . The first support plate 110 and the second support plate 120 may each form a long plate shape in the X direction.

The first support plate 110 and the second support plate 120 are coupled by a plurality of bolts or rivets R while being spaced apart from each other in the Y direction. A plurality of holes H1 to which rivets R are coupled may be formed in the first support plate 110 and the second support plate 120 .

A pair of rollers 130 is rotatably provided between the first support plate 110 and the second support plate 120 . A pair of holes H2 into which the rotation shafts of the rollers 130 are inserted (coupled) may be formed in each of the first support plate 110 and the second support plate 120 .

A hole H3 into which both shafts of the first shaft member 300 to be described later are inserted (coupled) may be formed in each of the first support plate 110 and the second support plate 120 . In addition, a hole H4 into which both shafts of the second shaft member 400 to be described later are inserted (coupled) may be formed in each of the first support plate 110 and the second support plate 120 .

1 to 3, the body 200 is configured to be coupled to the window (2). The body 200 is configured to include a first body 210 and a second body 220 .

As shown in Figure 1, the first body 210 is interposed between the lower portion of the window (2B) and the rail (3A). The first body 210 supports the load of the window 2 .

4 to 6 , a pair of contact members 210A may be coupled to the first body 210 . The contact members 210A are configured to contact the rail 3A when the body 200 is lowered. A hole H5 to which the contact members 210A are bolted may be formed in the first body 210 .

4 , a first inclined hole 211 and a second inclined hole 212 are formed in the first body 210 .

A first shaft member 300 is provided on the support member 100 . The first shaft member 300 may have a cylindrical shape. The first shaft member 300 may be provided as a roller bearing. A shaft of the first shaft member 300 may be inserted (coupled) to each of the first support plate 110 and the second support plate 120 . The axis of the first shaft member 300 may be parallel to the Y direction.

The first shaft member 300 is inserted into the first inclined hole 211 . The inner surface of the first inclined hole 211 includes a first inclined surface 211C, a first bottom surface, a 1A boundary surface 211A, and a 1B boundary surface 211B.

The first inclined surface 211C means an upper surface of the inner surface of the first inclined hole 211 . The first inclined surface 211C forms an inclined surface that rises in a direction away from the push member 920 . The cylindrical roller 130 of the first shaft member 300 is in contact with the first inclined surface 211C. The first shaft member 300 supports the body 200 through the first inclined surface 211C.

The first bottom surface means a lower surface of the inner surface of the first inclined hole 211 . The first bottom surface forms a surface parallel to the first inclined surface 211C. The first bottom surface is spaced apart from the first shaft member 300 by a small distance. The first bottom surface constrains the downward flow of the first shaft member 300 .

The 1A boundary surface 211A is located at the lower end of the first inclined surface 211C. The 1B boundary surface 211B is located at an upper end of the first inclined surface 211C.

In a state where the first shaft member 300 supports the body 200 through the first inclined surface 211C, the body 200 may rise or fall by the first inclined surface 211C. Describing the first shaft member 300 as a reference, the first shaft member 300 is a 1A interface 211A and a 1B interface 211B in a state where the body 200 is supported through the first inclined surface 211C. ) can be moved between

A second shaft member 400 is provided on the support member 100 . The second shaft member 400 may have a cylindrical shape. The second shaft member 400 may be provided as a roller bearing. The shaft of the second shaft member 400 may be inserted (coupled) to each of the first support plate 110 and the second support plate 120 . The axis of the second shaft member 400 may be parallel to the Y direction.

The second shaft member 400 is inserted into the second inclined hole 212 . The inner surface of the second inclined hole 212 includes a second inclined surface 212C, a second bottom surface, a 2A boundary surface 212A, and a 2B boundary surface 212B.

The second inclined surface 212C means an upper surface of the inner surface of the second inclined hole 212 . The second inclined surface 212C forms an inclined surface that rises in a direction away from the push member 920 . The cylindrical roller 130 of the second shaft member 400 is in contact with the second inclined surface (212C). The second shaft member 400 supports the body 200 through the second inclined surface 212C.

The second bottom surface means a lower surface of the inner surface of the second inclined hole 212 . The second bottom surface forms a surface parallel to the second inclined surface 212C. The second bottom surface is spaced apart from the second shaft member 400 by a small distance. The second bottom surface constrains the downward flow of the second shaft member 400 .

The 2A boundary surface 212A is located at the lower end of the second inclined surface 212C. The 2B boundary surface 212B is located at an upper end of the second inclined surface 212C.

In a state where the second shaft member 400 supports the body 200 through the second inclined surface 212C, the body 200 may rise or fall by the second inclined surface 212C. Describing the second shaft member 400 as a reference, the second shaft member 400 supports the body 200 through the second inclined surface 212C, and the 2A boundary surface 212A and the 2B boundary surface 212B are supported. ) can be moved between

As shown in FIG. 4 , the first inclined surface 211C and the second inclined surface 212C form the same inclination. The first shaft member 300 supports the first inclined surface 211C, and the second shaft member 400 supports the second inclined surface 212C. .

4, in a state in which the first shaft member 300 is in contact with the 1A interface 211A, and the second shaft member 400 is in contact with the 2A interface 212A, the first body ( 210 is maximally spaced upwards of the rail 3A. At this time, the contact member 210A is spaced apart from the upper side of the rail 3A.

The contact member 210A may be made of an elastically deformable material or shape. As the first shaft member 300 approaches the 1A interface 211A, the frictional force between the contact member 210A and the rail 3A may decrease. Immediately before the first shaft member 300 contacts the 1A interface 211A, the contact member 210A may be spaced apart from the rail 3A.

As shown in FIG. 6 , in a state where the first shaft member 300 approaches the 1B interface 211B, and the second shaft member 400 approaches the 2B interface 212B, the first body 210 ) is minimally spaced upwards of the rail 3A.

At this time, the load of the window 2 is transmitted to the rail 3A through the contact member 210A, and the contact member 210A forms a frictional force with the rail 3A. Therefore, even if the user pushes the window 2, the window 2 cannot be moved easily.

As shown in FIG. 4 , when the contact member 210A is spaced apart from the rail 3A, the load of the window 2 is transmitted to the rail 3A through the roller 130 . Accordingly, when the user pushes the window 2 , the window 2 can be easily moved along the longitudinal direction of the rail 3A.

2 and 3, the second body 220 is configured to include a fixed body (220A) and a separate body (220B). The fixed body 220A and the separation body 220B may each form a long plate shape in the Z direction.

The fixed body 220A extends from the first body 210 in the Z direction. The fixed body 220A and the separation body 220B are coupled by a plurality of bolts or rivets R while being spaced apart from each other in the Y direction. A plurality of holes H10 to which the rivets R are coupled may be formed in the fixed body 220A and the separation body 220B.

Holes H11 into which both protrusions 911A of the rack member 911 to be described later are movably inserted may be formed in each of the fixed body 220A and the separation body 220B. The hole H11 may have an elongated shape in the X direction.

Holes H12 into which both protrusions 914A of a latch 914 to be described later are movably inserted may be formed in each of the fixed body 220A and the separation body 220B. The hole H12 may have an elongated shape in the Y direction.

A hole H13 into which the shaft of the gear 913 is inserted (coupled) may be formed in each of the fixed body 220A and the separation body 220B. A rivet (R) may be used as the shaft of the gear (913).

3 and 4 , the first linker 600 is rotatably coupled to the first shaft member 300 . The first linker 600 may be configured to include a 1A linker 600A and a 1B linker 600B.

The 1A linker (600A) and the 1B linker (600B) are spaced apart from each other in the Y direction. 1A linker (600A) and 1B linker (600B) may form a plate shape side by side with each other. A pair of holes H6 into which both axes of the first shaft member 300 are rotatably inserted may be formed in each of the 1A linker 600A and the 1B linker 600B.

A third shaft member 500 and a locking member 610 are provided between the 1A linker 600A and the 1B linker 600B. The third shaft member 500 and the locking member 610 may be provided as roller bearings, respectively. The axes of the third shaft member 500 and the locking member 610 may be parallel to the Y direction.

A hole H7 into which the shaft of the third shaft member 500 is inserted (coupled) may be formed in the 1A linker 600A and the 1B linker 600B. And the 1A linker 600A and the 1B linker 600B may have a hole H8 into which the shaft of the locking member 610 is inserted (coupled). The first shaft member 300 and the locking member 610 may be provided on opposite sides with respect to the third shaft member 500 .

3 and 4 , the second linker 700 is rotatably coupled to the first body 210 . A hole H9 into which the shaft of the second linker 700 is inserted (coupled) may be formed in the first body 210 .

The second linker 700 forms a link hole 701 . The third shaft member 500 is inserted into the link hole 701 .

6 to 8, in a state in which the first shaft member 300 supports the body 200 through the first inclined surface 211C, the body 200 is formed by the first inclined surface 211C. can rise or fall. When the body 200 rises or falls by the first inclined surface 211C, the first linker 600 and the second linker 700 rotate in conjunction with the movement of the body 200 .

In a state in which the first shaft member 300 is caught on the 1A interface 211A, the link hole 701 forms an elongated shape along the circumferential direction around the first shaft member 300 . Therefore, in a state in which the first shaft member 300 is caught on the 1A interface 211A, the third shaft member 500 is positioned at the lower end of the link hole 701 by gravity.

4 to 6, in a state in which the first shaft member 300 is caught on the 1A interface 211A, even if the second linker 700 does not rotate, the first linker 600 is the first shaft It can rotate around the member 300 .

As shown in FIG. 1 , a locking jaw 800 is provided on a lower sill of the window frame 3 . The locking jaw 800 has a configuration in which the locking member 610 of the first linker 600 is caught. The locking jaw 800 may be fixed to the lower frame (sill) of the window frame (3) by a bolt. A hole H14 into which the bolt is inserted may be formed in the locking jaw 800 .

As shown in FIG. 4 , the locking jaw 800 forms a first slope 801 and a second slope 802 . Upper ends of the first slope 801 and the second slope 802 may be connected to each other.

When the window 2 is opened, the engaging member 610 of the first linker 600 contacts the first slope 801 . The first slope 801 forms an inclined surface that rises toward the X direction.

When the window 2 is closed, the engaging member 610 of the first linker 600 is in contact with the second inclined surface 802 . The second inclined surface 802 forms an inclined surface that descends toward the X direction.

The first slope 801 forms a steeper slope than the second slope 802 . Therefore, when the window 2 is closed than when the window 2 is opened, the engaging member 610 may easily cross the engaging sill 800 .

4, the intermittent unit 900 is configured to block the lowering of the body 200 by the first inclined surface 211C. The intermittent unit 900 blocks the lowering of the body 200 by the first inclined surface 211C in a state in which the window 2 is opened.

The intermittent unit 900 is configured to include a push member 920 and an intermittent unit 910 .

The push member 920 is configured to push the rack member 911 when the window 2 is closed. The push member 920 is coupled to the side frame (jamb) of the window frame (3). The push member 920 has a shape protruding in the X direction.

3 and 4 , the intermittent part 910 is provided in the second body 220 .

The intermittent unit 910 is configured to include a rack member 911 , a first elastic member 912 , a gear 913 , a latch 914 , and a second elastic member 915 . Each of the components of the intermittent unit 910 is provided between the fixed body 220A and the separation body 220B.

6 and 7, the rack member 911 is configured to be pushed by the push member 920 when the window 2 is closed. Protrusions 911A are formed on both sides of the rack member 911 .

Holes H11 into which both protrusions 911A of the rack member 911 are movably inserted in the X direction are formed in each of the fixed body 220A and the separation body 220B. The rack member 911 is pushed in the X direction by the push member 920 when the window 2 is closed.

The first elastic member 912 is configured to push the rack member 911 toward the push member 920 . The first elastic member 912 may be provided as a compression spring. As shown in FIG. 4 , the rack member 911 is moved in the -X direction by the first elastic member 912 when not pushed by the push member 920 .

The gear 913 is configured to rotate by the rack member 911 . A hole H13 into which the shaft of the gear 913 is inserted (coupled) is formed in each of the fixed body 220A and the separation body 220B.

One or more gears 913 teeth are formed on the lower portion of the rack member 911 . The rack member 911 is engaged with the gear 913 through the gear 913. Accordingly, when the rack member 911 moves, the gear 913 rotates.

The latch 914 is engaged with the gear 913 and is configured to move in the vertical direction. Projections 914A are formed on both sides of the latch 914 . Holes H12 into which both protrusions 914A of the latch 914 are movably inserted in the Y direction are formed in each of the fixed body 220A and the separation body 220B. 6 and 7, the latch 914 rises in the Z direction when the window 2 is closed.

The second elastic member 915 is configured to push the latch 914 to prevent rotation of the second linker 700 . The second elastic member 915 may be provided as a compression spring.

The second elastic member 915 is interposed between the rack member 911 and the latch 914 . The latch 914 is positioned at the lowermost position by the elastic recovery force of the second elastic member 915 in a state engaged with the gear 913 .

7 and 8 , a pusher 916 may be interposed between the second elastic member 915 and the rack member 911 . The pusher 916 may be made of a material having a small coefficient of friction. The pusher 916 forms a relatively small frictional force with the bottom surface of the rack member 911 when the rack member 911 moves in the horizontal direction.

1 shows a state in which the window 2 is opened. When the user pushes the window 2 in the -X direction with reference to FIG. 1 , the side portion (style) of the window frame (2B) is closer to the side frame (jamb) of the window frame (3), and the window (2) is closed.

4 to 6 mean a state in which the side part (style) of the window frame (2B) is approaching the side frame (jamb) of the window frame (3), and FIG. 7 means a state in which the window (2) is completely closed.

Hereinafter, for easy understanding of the present invention, a clockwise direction and a counterclockwise direction will be separately described in the state shown in the drawings.

As shown in FIG. 4 , in the state in which the window 2 is opened, the first shaft member 300 is in contact with the first A boundary surface 211A. That is, in the state in which the window 2 is opened, the body 200 is raised. Accordingly, when the user pushes the window 2 , the window 2 can be easily moved along the longitudinal direction of the rail 3A.

In order to descend the body 200 in the state shown in Figure 4, the second linker 700 must be rotated counterclockwise (see Figure 7). However, in the open state of the window 2 , the counterclockwise rotation of the second linker 700 is blocked by the latch 914 .

Accordingly, the body 200 cannot be lowered by gravity while the window 2 is open. In a state in which the first shaft member 300 is caught on the 1A interface 211A, the third shaft member 500 is positioned at the lower end of the link hole 701 by gravity.

In a state in which the first shaft member 300 is caught on the 1A interface 211A, the first linker 600 may rotate around the first shaft member 300 even if the second linker 700 does not rotate. . Accordingly, as shown in FIG. 5 , in the process of closing the window 2 , the locking member 610 may rise from the second slope 802 to cross the locking sill 800 .

As shown in FIG. 6 , in the process of closing the window 2 , the push member 920 pushes the rack member 911 in the X direction. Accordingly, the gear 913 rotates clockwise, and the latch 914 rises. 6 shows the moment when the latch 914 is raised and the counterclockwise rotation of the second linker 700 is possible.

As shown in FIG. 7 , the window 2 is completely closed and the body 200 is lowered by gravity. The first shaft member 300 is brought closer to the 1B interface (211B). At this time, the load of the window 2 is transmitted to the rail 3A through the contact member 210A. The contact member 210A forms a frictional force with the rail 3A. Therefore, the window 2 does not open easily.

In a state where the first shaft member 300 is not caught on the 1A interface 211A, if the second linker 700 does not rotate, the first linker 600 may rotate around the first shaft member 300 . none.

Accordingly, as shown in FIG. 8, when the user pushes the window 2 to be opened in a state in which the window 2 is completely closed, the first linker 600 is caught on the engaging jaw 800 and the body 200 is first 1 It rises by the inclined surface 211C. In this process, the second linker 700 rotates clockwise.

After that, when the first shaft member 300 is caught on the 1A interface 211A, the first linker 600 is rotated by the first inclined surface 801 and is removed from the locking jaw 800 .

As the window 2 is opened, the rack member 911 moves again in the -X direction by the elastic recovery force of the first elastic member 912 . At this time, the gear 913 rotates counterclockwise, and the latch 914 descends. Accordingly, the counterclockwise rotation of the second linker 700 is again blocked by the latch 914 .

When the first shaft member 300 is caught on the 1A interface 211A, the contact member 210A is spaced apart from the upper side of the rail 3A. The load of the window 2 is transmitted to the rail 3A through the roller 130 . Thus, the window 2 can be easily moved again along the longitudinal direction of the rail 3A.

The conventional system window opening and closing device has the inconvenience of opening the window only when the handle is rotated by a certain angle or more. People with low motor skills, such as the elderly or young children, may have difficulty in rotating the handle.

In addition, the lift sliding system windows, which can be opened only by rotating the handle, can act as a factor to delay the escape speed when a similar situation occurs, such as when an indoor fire occurs. Therefore, the installation rate of lift sliding system windows is not high in facilities related to the elderly or children, such as nursing homes and kindergartens.

As described above, the touch-lever type lift and sliding device 10 according to an embodiment of the present invention can open the window 2 or the door regardless of the rotation angle of the handle.

When a rotary handle is installed on the window 2 or the door, the rotation angle of the handle for opening the window 2 or the door may be less than 45 degrees.

When a fixed handle is installed on the window 2 or the door, the rotation angle of the handle for opening the window 2 or the door may be 0 degrees. Therefore, the touch-lever type lift sliding device 10 according to an embodiment of the present invention solves the problems of the conventional system window opening and closing device.

According to the present invention, when the window is pushed to be opened, the body rises by the first inclined surface while the first linker is caught on the locking jaw, thereby forming a simple structure, and holding the window by rotating the handle within 45 degrees while the window is locked. It is possible to provide a touch-lever type lift sliding device that is opened while pulling.

In the foregoing, specific embodiments of the present invention have been described and illustrated, but it is common knowledge in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have Accordingly, such modifications or variations should not be individually understood from the technical spirit or point of view of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: lift device
100: support member 600: first linker
110: first support plate 600A: 1A linker
120: second support plate 600B: 1B linker
130: roller 610: locking member
200: body 700: second linker
210: first body 701: link hole
211: first inclined hole 800: locking jaw
211C: first slope 801: first slope
211A: 1A interface 802: second slope
211B: 1B interface 900: intermittent unit
212: second inclined hole 910: intermittent unit
212C: second inclined surface 911: rack member
212A: 2A interface 911A: protrusion
212B: 2B interface 912: first elastic member
210A: contact member 913: gear
220: second body 914: latch
220A: fixed body 914A: protrusion
220B: separation body 915: second elastic member
R: Rivet 916: Pusher
300: first shaft member 920: push member
400: second shaft member
500: third shaft member
1: window
2: window 3: window frame
2A: Glass 3A: Rail
2B : window

Claims (8)

a support member to which a roller rolling along the rail of the window frame is rotatably coupled;
The window is coupled, the body forming a first inclined surface;
a first shaft member provided on the support member and supporting the first inclined surface;
a first linker rotatably coupled to the first shaft member; and
Including a locking sill provided on the window frame,
When the window is pushed to open, the body lifts by the first inclined surface while the first linker is caught on the locking jaw. According to claim 1,
The body forms a second inclined surface,
The support member includes a second shaft member supporting the second inclined surface. According to claim 1,
The locking jaw forms a first slope surface in contact with the first linker,
The body forms a 1A interface at the lower end of the first inclined surface,
When the first shaft member is caught on the interface 1A when the window is opened, the first linker is rotated by the first slope and is removed from the locking jaw. According to claim 1,
a second linker rotatably coupled to the body and forming a link hole;
a third shaft member provided on the first linker and inserted into the link hole; and
When the window is opened, the lift sliding device comprising a control unit for blocking the lowering of the body by the first inclined surface. 5. The method of claim 4,
The locking protrusion forms an inclined surface in contact with the first linker,
The body forms a 1A interface at the lower end of the first inclined surface,
When the first shaft member is caught on the 1A interface, the link hole is elongated in the circumferential direction around the first shaft member so that the first linker rotates by the slope. Lift, characterized in that sliding device. 6. The method of claim 5,
The slope is
a first slope to which the first linker contacts when the window is opened; and
The first linker is in contact with the window when the window is closed, and comprises a second inclined surface connected to the first inclined surface and each other at an upper end,
The lift sliding device, characterized in that the first inclined surface forms a steeper inclination than the second inclined surface. 5. The method of claim 4,
The control unit is
a push member coupled to the window frame; and
It includes an intermittent unit provided on the body,
The control unit,
a rack member pushed by the push member when the window is closed;
a first elastic member for pushing the rack member toward the push member;
a gear rotating by the rack member; and
Lift sliding device, characterized in that it comprises a latch that moves in engagement with the gear so as to selectively block the rotation of the second linker. 8. The method of claim 7,
and the intermittent unit includes a second elastic member interposed between the rack member and the latch to push the latch toward preventing rotation of the second linker.

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