NL2009694C2 - SLIDING PANEL SYSTEM. - Google Patents

Description

Sliding panel system

The invention relates to a sliding panel system, comprising at least one guide rail extending in a longitudinal direction, a sliding panel extending in a main direction substantially transversely of the longitudinal direction of the guide rail, at least one axis connected to the sliding panel and extending in axial direction extends substantially transversely to the main direction of the sliding panel and substantially transversely to the sliding direction, and at least one guide element supported by the shaft, with the aid of which the panel can be moved along the guide rail in the longitudinal direction.

In such a sliding panel system, which is known from EP0699266B1, a sliding panel can be slid over a horizontal rail of a frame. The sliding panel comprises wheels which are rotatably mounted about a rotation axis, wherein the sliding panel can be moved over the horizontal rail by means of the wheels. The wheels are further pivotable about a pivot axis which extends in the longitudinal direction of the horizontal rail and is spaced apart from the axis of rotation.

The sliding panel is slidable with respect to the frame in the longitudinal direction of the horizontal rail between an open and a closed position, wherein in the closed position an opening located in the frame is covered by means of the sliding panel, which opening in the open position has been released. The sliding panel is also movable in a direction transverse to the horizontal rail from a position in which the sliding panel abuts the frame to a position in which the sliding panel is spaced apart from the frame by pivoting the wheels relative to the frame. vice versa. During the pivoting movement of the wheel, the wheel remains in contact with the horizontal rail. In the position in which the sliding panel is spaced from the frame, the wheel is placed at an angle with respect to the sliding panel surface. While the sliding panel is moving over the horizontal rail, the wheel remains at an angle with the sliding panel surface.

It is a drawback of the known sliding panel system that relatively many parts are required to manufacture the sliding panel system which has a sliding panel that is both slidable over the horizontal rail in the frame, and that is displaceable in a direction transverse to the horizontal rail.

Furthermore, it is a disadvantage of the prior art that the wheel is at an angle with the sliding panel surface during the movement along the horizontal rail. As a result, the wheel is relatively unstable on the rails and the wheel can be released relatively easily from the rails.

It is further a disadvantage of the known sliding panel system that a user must exert a relatively great force during the movement of the sliding panel in the direction transverse to the horizontal rail in order to lift the sliding panel to pass a bi-stable point.

It is an object of the present invention to provide a sliding panel system that has relatively few parts and that is easy to operate by a user.

The object of the invention is achieved with the sliding panel system according to the present invention in that the shaft is at least slidable in the axial direction with respect to the guide element, whereby the panel connected to the shaft is displaceable in axial direction from a first position to a second position and vice versa.

The panel is moved from a first position to a second position and vice versa by moving the panel in the axial direction of the axis, the guide element remaining in the same position with respect to the guide rail.

In the first position the sliding panel can for instance close an opening and be blocked against sliding along the guide rail, while in the second position the sliding panel can easily be slid.

A user can exert a uniform pushing and / or pulling force to move the sliding panel from the predetermined first position to the predetermined second position. The user does not have to exert peak forces on the sliding panel to lift the sliding panel over a bi-stable point, which makes the operation of the sliding panel system relatively simple. In addition, the guide element retains the same orientation with respect to the guide rail in both the first and the second position. An additional advantage is that the guide rail over almost the entire length can be designed as a straight rail, which makes the production of such a guide rail simple.

An embodiment of the sliding panel system according to the invention is characterized in that the panel can be slid over the axis in axial direction over a distance of at least 5 millimeters.

The distance to be bridged during the displacement of the sliding panel in the axial direction of the axis should be sufficiently large to bring the sliding panel into a position in which it can be freely moved over the guide rail.

An embodiment of the sliding panel system according to the invention is characterized in that the axial direction includes an angle of more than zero degrees with the horizontal, the main direction including an angle of less than 90 degrees with the horizontal.

With such a location of the shaft and if the guide rail extends, for example, horizontally, because the shaft extends substantially transversely to the main direction of the sliding panel, the sliding panel will enclose an angle with a plane extending vertically. As a result, the sliding panel will, as it were, lean forward or backward. As a result, when the axis is moved in the axial direction with respect to the guide element, a force in the axial direction will be exerted on the sliding panel by the force of gravity acting on the sliding panel.

When the sliding panel is moved downwardly in the axial direction relative to the guide rail, gravity simplifies the effort that a user must make to move the sliding panel, that is, the force that the user must exert to effect the movement.

At a certain value of the angle, the friction prevailing between the axis and the sliding panel is exceeded. As a result of this overrun, the sliding panel can be moved in the axial direction of the axis in the direction of the axial component of gravity without the force of the user exerted on the sliding panel. The size of this angle will depend on the applied combination of materials, weights, dimensions of the various components of the sliding panel system.

An embodiment of the sliding panel system according to the invention is characterized in that the sliding panel comprises a housing for the shaft, wherein a first end of the shaft is connected to a first housing wall and a second second end of the shaft opposite the first end of the shaft is connected to a second housing wall.

The housing of the shaft can be mounted on one side of the sliding panel, but can also be accommodated in a recess in the sliding panel. A housing accommodated in a recess of the sliding panel has the advantage that the shaft and the guide element mounted on the shaft are hidden from the eye of the user and thus do not adversely affect the aesthetic appearance of the sliding door.

An embodiment of the sliding panel system according to the invention is characterized in that the first housing wall and / or the second housing wall form a stop for the guide element mounted on the shaft.

The stops formed by the first and / or second housing wall limit the displacement of the sliding panel, and prevent the sliding panel from being moved over too great a distance.

An embodiment of the sliding panel system according to the invention is characterized in that the sliding panel system comprises at least a set of moving means, a first moving means of which is fixedly connected to the sliding panel and a second moving means is fixedly connected to the guide rail, and wherein the first moving means and the second moving means, when in moving contact with each other, causes a movement of the sliding panel in the axial direction of the shaft.

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The moving means in moving contact with each other force a movement of the sliding panel in the axial direction of the axis from the first position to the second position and / or vice versa. A displacement of the sliding panel in the longitudinal direction of the gel derail means a displacement in the axial direction of the shaft and the sliding panel connected thereto.

An embodiment of the sliding panel system according to the invention is characterized in that the first and second displacement means comprise cams cooperating with each other.

The co-operating cams can comprise a cam with a chamfered end, the cam with the chamfered end abutting against a chamfered or not chamfered, in such a way that the sliding panel connected to one of the two cams is forced to move in the axial direction of the axis.

An embodiment of the sliding panel system according to the invention is characterized in that the first and / or second displacement means have a contact surface which includes an angle of inclination with a surface extending transversely to the axial direction.

Because the displacement means provided with an inclined contact surface comes into movable contact with the other displacement means, the sliding panel is driven in the axial direction of the shaft. The distance over which this occurs relative to the distance in the longitudinal direction of the guide path depends on the angle of inclination of the displacement means and will be in the order of Y * tan (A), where Y is the distance in the longitudinal direction of the guide path and A is the angle of inclination of the displacement means.

An embodiment of the sliding panel system according to the invention is characterized in that the sliding panel system is provided with a frame comprising the rail, as well as with a seal located between the frame and the sliding panel.

The seal provided between the frame and the sliding panel is intended for water-tight and / or airtight sealing of the sliding panel. In particular when applied to vessels, it is important that sliding panels connect watertight to create watertight compartments in the vessel in that way. The seal can be attached to the frame or to the sliding panel.

An embodiment of the sliding panel system according to the invention is characterized in that the seal is provided with a rigid carrier element comprising a slot and with a flexible sealing element partly located in the slot.

A two-part sealing element has the advantage that the flexible sealing element can be replaced without having to remove the entire sealing element. The flexible sealing element can be a consumable item that can be replaced after wear in order to continue to guarantee the water and / or air tightness between the frame and the sliding panel.

An embodiment of the sliding panel system according to the invention is characterized in that the sliding panel is slidable in the axial direction along the axis from the first position in which the flexible sealing element is pressed between the frame and the sliding panel to the second position in which the flexible sealing element lies freely between the frame and the sliding panel and vice versa.

In the first position, a watertight and / or airtight connection has been created between the frame and the sliding panel, because the flexible sealing element, for instance manufactured from a rubber, EPDM or any elastic deformable material suitable for this purpose, abuts against both the frame and the frame. as the sliding panel.

If the seal with the flexible seal element is connected to the frame, the flexible seal element in the second position is free from the sliding panel or vice versa. The flexible sealing element is then not depressed, and the frame and the sliding panel are then spaced apart so that the sliding panel 25 can be shifted over the guide rails without adjacent contact of the sealing element.

The minimum distance over which the sliding panel is axially slidable about the axis is determined by the distance that the sliding panel must bridge in order for the flexible sealing element to move from the pressed-in state to the non-pressed-in state. The maximum distance over which the sliding panel can move in the axial direction is determined by the length of the shaft, which must in any case be greater than the distance that the sliding panel must bridge around the flexible sealing element from the pressed-in state to the non-pressed-in state to pass.

An embodiment of the sliding panel system according to the invention is characterized in that the guide element is a running wheel which is mounted rotatably and axially displaceably on the shaft.

A running wheel as a guide element has the advantage that a displacement in the longitudinal direction of the guide rail will take place with only very slight friction between the guide rail and the sliding panel. In the case of a running wheel, the axle has a dual function. On the one hand, the axis has the function of axis of rotation for the running wheel, and, on the other hand, the axis has the function of sliding axis over which the running wheel can be moved axially. By combining multiple functions in a component, the number of components of the sliding panel system is kept relatively small.

An embodiment of the sliding panel system according to the invention is characterized in that the sliding panel system comprises a locking arrangement for locking the sliding panel in the first or second position.

The locking device preferably locks the sliding panel in a position in which the sliding panel rests against a frame, whether or not provided with a sealing means placed between the sliding panel and the frame. In particular when the sliding panel system is mounted on a vessel as a watertight door, it is important that the locking device is securely lockable in order to prevent undesired opening of the sliding panel in the event of a mass of water acting on the sliding panel.

All this will be clarified with reference to the following figures, in which:

FIG. -I-C show respectively a front view of a frame of the sliding panel system, a front view of the upper guide rail and a front view of the lower guide rail;

FIG. 2A-D a front view, a right-hand cross-section along the line A-A and a left-hand cross-section along the line B-B and a detailed view of FIG. 2B of a sliding panel system according to the invention;

FIG. 3 shows a detail section of an upper frame element and a seal according to FIG. 2D;

FIG. 4A-C show respectively a front view, a side view and a top view of the guide element of the sliding panel system according to the invention shown in Figs. 2A-D; and

FIG. 5 shows a detailed view of cooperating displacement means according to FIG. 33 and FIG. 2A-D,

In the figures, corresponding parts are provided with the same reference numerals.

Figures 1A-C, 2A-D, 3,4A-C and 5 show a sliding panel system according to the invention, which comprises a frame 1 and a sliding panel 2 included in the frame 1.

Figure 1A shows the frame 1 which comprises an upper frame element 3 and a lower frame element 4 placed at a distance from the upper frame element 3. The upper frame element 3 and the lower frame element 4 are connected by means of a first post 5 and a second post 6 placed at a distance from the first post 5. The upper frame element 3, the lower frame element 6 , the first post 5 and the second post 6 form a perimeter that defines an aperture 7.

The upper frame element 3 and the lower frame element 4 are provided with an upper guide rail 8 and a lower guide rail 9, respectively, which extend in the longitudinal direction of the upper and lower frame element 3, 4, respectively, and extend over a dense wall 10.

Figure B shows the upper guide rail 8 and cams 11,13 placed on the upper guide rail 8.

Figure 1C shows the lower guide rail 9 and cams 12,14 placed on the lower guide rail 9. The cams 11,12 which are placed in the vicinity of the first post 5 are placed closer to a longitudinal edge of the upper guide rail 8 or the lower guide rail 9, respectively, than the cams 13 and 14 which are placed in the vicinity of the second post 6 .

Figure 2A shows the sliding panel 2 which is provided with an upper side 15, a lower side 16 opposite the upper side 15, a first side 17 and a second side 18 opposite the first side 17. The sliding panel 2 is furthermore provided with a button 19 , a lock 20 and a transparent window 21 or not.

At the top 15 and at the bottom 16, the sliding panel 2 is provided with a thickening 22 and a thickening 23. In the thickening 22 on the top 15 of the sliding panel 2, two recesses 24, 25 are arranged, the recess 24 in the vicinity of the first side 17 is situated and the recess 25 is situated in the vicinity of the second side 18. In the bulge 23 on the underside 16 of the sliding panel 2, two recesses 26, 27 are provided, the recess 26 being located in the vicinity of the first side 18 and the recess 27 being located in the vicinity of the second side 19.

In each of the recesses 24, 25, 26, 27 a housing 28 is placed, in which a shaft 29 is mounted. A running wheel 30 is rotatably mounted about the shaft 29. Also, in each of the recesses 24, 25, 26, 27, a cam 31, 32, 33, 34 is attached to the respective housing 28. The cam 31 is further from the top 15 is placed away from the sliding panel 2 than the cam 33. The cam 32 is placed further away from the underside 16 of the sliding panel 2 than the cam 34.

Figures 2B and 2C show a cross-sectional view of the sliding panel assembly according to the invention along the section line A-A and section section B-B, respectively. The sliding panel 2 can be moved in the direction of the arrow P3 in the direction of the frame 1 and can be moved in the direction of the arrow P4 in the direction away from frame 1.

The sliding panel 2 is placed at a small angle B of, for example, 5 to 10 degrees with respect to the vertical.

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A detail of Figure 2C shown in the circle is shown in Figure 2D. Figure 2D shows a spacer 35 connected to the upper frame element 3. The upper guide rail 8 is attached to the spacer 35.

Placed in the bulge 22 of the sliding panel 2 is the housing 28 which is provided with a first housing wall 36 and a second housing wall 37 opposite the first housing wall 36. A distance E is the distance between the first housing wall 36 and the second housing wall 37 The shaft 29 is placed between the first housing wall 36 and the second housing wall 37. The running wheel 30 is mounted axially displaceably and rotatably mounted on the shaft 29. The thickness e of the running wheel is for example a factor 2 to 3 smaller than the distance. E between the first housing wall 36 and the second housing wall 37. The shaft 29 is displaceable relative to the running wheel 30 over a distance of at least 5 millimeters, for example 6 millimeters.

A sealing element 40 is fixedly connected to the upper frame element 3.

Figure 3 is an enlarged detail view of the seal 40 which is attached to the upper frame element 3. The seal 40 is provided with a rigid carrier part 41. The rigid carrier part 41 is connected to the upper frame element by means of a screw 42 3. A passage opening for the screw 42 is provided in a slot 43 of the rigid carrier part 41.

The carrier part 41 is provided with two T-shaped parts 44 protruding on the side of the rigid carrier part 41 remote from the frame element 3. A flexible sealing element 45 provided with recesses is placed over the T-shaped parts 44 of the rigid carrier part 41 and at least partially in the slot 43 of the rigid carrier part 41. On the side of the flexible sealing element 45 remote from the upper frame element 3, this is provided with a lip 47.

Figures 4A-C respectively show a front view, a side view and a top view of the housing 28, which is provided with the first housing wall 36 and the second housing wall 37. The cam 31 is fixedly attached to the second 11 housing wall 37.

The cam 31 has a chamfered surface 46. The chamfered surface 46 is at an angle A with respect to the surface that is transverse to the axis C of the shaft 29.

Figure 5 shows the cam 31 of the sliding panel 2 approaching the cam 11 of the guide rail 8. The cam 11 is fixedly positioned with respect to the upper guide rail 8. The arrow P3 indicates the direction in which the sliding panel 2 and the cam 31 connected to the sliding panel 2 move when the cam 31 comes into contact with the cam 11 and becomes moved in the direction of arrow Pi. The arrow P4 indicates the opposite direction of the arrow P3.

In an opened position, the sliding panel 2 is placed at least partially in front of the wall 10. The sliding panel system is brought from the opened position to a closed position by moving the sliding panel 2 over the lower and upper guide rails 8, 9 in the longitudinal direction of the guide rails 8 9 in the direction indicated by arrow Pi until the sliding panel 2 covers the opening 7. For this purpose the running wheels 30 are in contact with the lower and upper guide rail 8, 9. The running wheels 30 rotate about the axis 29 and therefore provide for a relatively low-friction displacement of the sliding panel 2 over the guide rails 8, 9. For moving the sliding panel 2 from the closed position to the open position, the sliding panel 2 is moved in the opposite longitudinal direction of the guide rails 8, 9 in the direction indicated by the arrow P2.

The displacement of the sliding panel in the direction of the frame 1 is forced by the cams 11,12,13,14 which are attached to the sliding panel 2 and which co-operate with the cams 31, 32, 33, 34 attached to the guide rails 8, 9. When the closing position is reached, the cams 11, 12, 13, 14 come into contact in pairs with the respective cams 31, 32, 33, 34, and a movement of the cams 11, 12, 13, 14 attached to the sliding panel 2 the longitudinal direction Pi of the guide rails 8, 9 then results in a movement of the sliding panel 2 in the direction P3 of the frame 1. All this is clarified in Figure 5 in which the arrow Pi is the direction of movement of the sliding panel 2 in the longitudinal direction of the guide rail 8, 9 and the arrow P3 is the resulting movement of the sliding panel 2 in the direction of the frame 1. A beveled surface 39 of the cam 11 is in slidable contact with the sloping surface 46 of the cam 31.

When the sliding panel 2 is displaced in the direction P1 or P2 relative to the frame 1, the running wheel 30 remains connected to the upper guide rail 8. The sliding panel 2 and the shaft 29 move in the axial direction of the shaft 29 relative to the frame. running wheel 30. The running wheel 30 can move inside the housing 28 in the axial direction of the shaft 29 and is retained by the first and second housing wall 36, 37. The first and second housing wall 36, 37 act as a stop so that the maximum displacement of the running wheel 30 along the axis 29, and therefore also the maximum displacement of the sliding panel 2 in the direction of the frame 1, is determined by the distance E between the first and second housing wall 36, 37.

The sliding panel 2 is movable in the direction P3 towards the frame 1 until the sliding panel 2 in the closed position abuts the seal 40. The seal 40, and in particular the flexible sealing element 45, is pressed in the closed position between the frame 1 and the sliding panel 2, thereby forming a watertight and / or airtight connection between the frame 1 and the sliding panel 2. When the sliding panel 2 is displaced in a direction away from the frame 1, the flexible sealing element becomes again and takes its original, uncompressed form.

When moving the sliding panel 2 in the longitudinal direction of the guide rails 8, 9 from the closed position to the open position and vice versa, to prevent the cams 31, 32 in the open position from coming into contact with the respective cams 13 14, the cams 31, 32 are placed at such a distance from the top 15 of the sliding panel 2 that, when the sliding door 2 is moved in the longitudinal direction of the guide rails 8, 9, the cams 31, 32 the cams 13, 14 can pass without coming into contact with each other.

When the sliding panel 2 is placed at a small angle B, for example 6 degrees, with respect to the vertical, and the shaft 29 is also placed at the same angle 13 B with the horizontal, the sliding panel 2 can be moved from the closed position to the closing position in that the sliding panel 2 is displaced by gravity in the downward axial direction of the shaft 29. For this purpose, only the frictional force present between the running wheel 30 and the shaft 29 must be overcome. A user therefore only needs to exert a slight force to move the sliding panel 2 from the closed position to the closed position.

Alternatively, the guide element can be designed as a slidable block-shaped part that is slidable in the longitudinal direction of the guide rail 20. The block-shaped part is preferably embodied in a hard plastic, so that the block-shaped part can slide well over the guide rail.

Alternatively, the sliding panel system can be designed with a single guide rail, the guide rail then being in contact with the sliding panel at the top of the sliding panel.

Alternatively, the sliding panel can be designed as a sliding window. 15

Claims (13)

A sliding panel system, comprising at least one guide rail (8) extending in a longitudinal direction, a sliding panel (2) extending in a main direction substantially transversely of the longitudinal direction of the guide rail (8), at least one with the sliding panel (2) ) connected shaft (29) extending axially substantially transversely to the main direction of the sliding panel (2) and substantially transversely to the sliding direction, and at least one guide element (30) supported by the shaft (29) by means of which the sliding panel (2) is movable in the longitudinal direction over the guide rail 10 (8), characterized in that the shaft (29) can be displaced at least in the axial direction with respect to the guide element (30), so that it can be moved with the shaft (29) ) connected sliding panel (2) is movable in axial direction from a first position to a second position and vice versa. Sliding panel system according to claim 1, characterized in that the sliding panel (2) can be slid in axial direction over the axis (29) over a distance of at least 5 millimeters. 3. Sliding panel system according to any one of the preceding claims, characterized in that the axial direction encloses an angle of more than zero degrees with the horizontal, the main direction enclosing an angle of less than 90 degrees with the horizontal. A sliding panel system according to any one of the preceding claims, characterized in that the sliding panel (2) comprises a housing (28) for the shaft (29), wherein a first end of the shaft (29) is connected to a first housing wall ( 36) and a second second end of the shaft (29) opposite the first end of the shaft (29) is connected to a second housing wall (37). Sliding panel according to claim 4, characterized in that the first housing wall (36) and / or the second housing wall (37) form a stop for the guide element (30) supported by the shaft (29). Sliding panel system according to one of the preceding claims, characterized in that the sliding panel system comprises at least one set of displacement means (11, 12, 13, 14; 31, 32, 33, 34), a first displacement means (31, 32, 33) of which 34) is rigidly connected to the sliding panel and a second displacement means (11, 12, 13, 14) is rigidly connected to the guide rail (8, 9), and wherein the first displacement means (31, 32, 33) 34) and the second displacement means (11, 12, 13, 14), when in moving contact with each other, cause displacement of the sliding panel (2) in the axial direction of the shaft (29). 7. Sliding panel system according to claim 6, characterized in that the first and second displacement means comprise cams cooperating with each other. Sliding panel system according to claim 6, characterized in that the first and / or second displacement means have a contact surface (39, 46) which includes an angle of inclination (A) with a surface extending transversely to the axial direction. 20 Sliding panel system according to one of the preceding claims, characterized in that the sliding panel system is provided with a frame (1) comprising the rail and with a seal (40) located between the frame (1) and the sliding panel (2). Sliding panel system according to claim 9, characterized in that the seal (40) is provided with a rigid carrier element (41) comprising a slot (43) and with a flexible sealing element (45) partially located in the slot. Sliding panel system according to claim 10, characterized in that the sliding panel (2) is slidable in axial direction along the axis (29) from the first position in which the flexible sealing element (45) between the frame (1) and the sliding panel (2) ) is pressed to the second position in which the flexible sealing element (45) lies freely between the frame (1) and the sliding panel (2) and vice versa. 5 A sliding panel system according to any one of the preceding claims, characterized in that the guide element (30) is a running wheel which is rotatably and axially displaceably mounted on the shaft (29). A sliding panel system according to any one of the preceding claims, characterized in that the sliding panel system comprises a locking device (20) for locking the sliding panel (2) in the first or second position.