This invention relates to a sliding door or window, in particular a door or window of the type known in the jargon of the trade as “lift and slide”.
Sliding doors and windows of the lift and slide type are well known, and basically comprise:
It is also known that doors and windows of this type—but also traditional sliding doors and windows—can be fitted with an accessory consisting of at least one contact element or insert known in the jargon of the trade as “anti-lifting plug” to provide added protection and security.
This accessory is normally connected to the door or window, especially if the door or window separates an interior room from the outside, particularly on low storeys of a building (such as separation of the room from a garden).
These anti-lifting plugs comprise a base which can be connected to the sash profile and a peg or plug which is joined to or forms a single body with the base, and which projects from the sash profile zone (in particular that forming the upper horizontal member) opposite the corresponding inner zone of the fixed frame profile.
The anti-lifting plug is applied on the sliding sash to prevent it from being lifted and/or pulled up out of its lower guides: such lifting could cause the sash to fall accidentally during an incorrect operation, but above all, it could be the result of prowlers attempting to break in from the outside.
In doors and windows of the “lift and slide” type, considered here, anti-lifting plugs are used rarely because they are less effective than they are on traditional sliding doors and windows where, by comparison, they are used more much more frequently. In practice, in the plugs used up to now on “lift and slide” doors and windows, the working thickness which comes into contact with the fixed frame must be less than that of plugs applicable to traditional sliding doors and windows: if that were not so, the plug would prevent the sash from being lifted in order to open it.
When the sash is lowered and closed, however, the reduced thickness leaves a relatively large gap between the plug and the profile, enabling unwanted lifting of the sash even if closed.
Another drawback is that the anti-lifting plug, when fitted, can only be applied on the upper corner of the sash, close to the side in which the operating means and closing means are located, since the plug cannot be fitted to the sash until the sash has been installed on the respective fixed frame equipped with the tracks. This is because the presence of the plug would prevent normal installation operations.
Now the problem is that attempts to lift the sash may be tried on the opposite side of the sash to that fitted with the anti-lifting plug. In such a case, the lifting action, even though less simple, could still cause the sash to come out of the tracks, meaning that it could be forced open. This is more critical if the sash has large dimensions, both in height and length.
At present, the possibility of fitting an anti-lifting plug on sliding sashes of this type is unfeasible, since the upper corner of the sash furthest from the corner zone fitted with the anti-lifting plug is closed beforehand by a guard profile extending along the entire vertical member of the sash. This is designed to keep these zones closed without interruption, avoiding the entry of external agents and improving the appearance of the door or window as a whole.
This invention therefore has for aim to overcome these drawbacks by providing a sliding door/window, in particular a door/window of the type known in the jargon of the trade as “lift and slide”, offering a high level of security thanks to the presence of anti-lifting plugs built into the operating parts and structure of the door or window while maintaining the constructional architecture substantially unchanged.
According to the invention, the above aim is achieved by a sliding door/window, in particular a door/window of the “lift and slide” type, comprising the technical characteristics set out in one or more of the appended claims.
The technical features of the invention, with reference to the above aims, are clearly described in the claims below and its advantages are more apparent from the detailed description which follows, with reference to the accompanying drawings which illustrate a preferred embodiment of the invention provided merely by way of example without restricting the scope of the inventive concept, and in which:
With reference to the accompanying drawings, in particular
Besides the above, there may also be closing means (also not illustrated because they fall outside the scope of this invention) acting at least between the vertical member 12 of the sash 3 and the vertical member 2a of the fixed frame 2 which, in the closed configuration, abut against each other edge to edge thereby stabilizing the closed configuration.
The controlling member 6 and the operating means 7 are shown, at least partially in
Still with reference to
In other words, the first contact element 10 and the drive means 11 are mobile relative to each other.
In one preferred embodiment, the first contact element 10 is hinged at one end to the first slider 8, while the drive means 11 are stably fitted in the groove C (as described in more detail below): in this embodiment, therefore, the first contact element 10 moves and the drive means 11 remain fixed.
More precisely, the first slider 8 can be fitted close to the first top corner of the sash 3, made by the upper horizontal member 9 with the vertical member 12 abutting the vertical member 2a of the fixed frame 2 in the lowered, closed configuration.
The first slider 8 is also stably connected to the operating means 7 of the sash 3 through a right-angle drive 13 associated with the sash 3 at the upper corner of the sash 3.
In particular, the stable connection between the right-angle drive 13 and the first slider can be obtained by a further rod segment 22 slidably fitted in the groove C.
In structural terms, the first slider 8 comprises:
Obviously, as mentioned previously, the connection between the first slider 8 and the right-angle drive 13 can be obtained by interposing the rod segment 22 which is provided, at the ends of it, with holes for coupling to the pin 16 (first slider 8) and to a pin 13a (right-angle drive 13).
The first slider 8 also has two undercuts 17 positioned opposite each other on both sides along its bottom portion and designed to be slidably coupled in the groove C.
The accompanying drawings illustrate a preferred embodiment where both ends of the first slider 8 are provided with the above mentioned connecting means 16 (pins), so as to enable positioning in series of at least one second slider 8′, similar to the first slider 8, and with respective contact element 10′ and drive and positioning means 11′.
This connection may be obtained by a rod segment 21 also slidably housed in the groove C.
In this way, two or more sliders can be positioned in series along the upper horizontal member 12 of the sash 3 to make the sash 3 even more secure when in the lowered, closed position: for example, the second slider 8′ may be positioned near the other corner of the sash 3 (by making the rod segment 21 of suitable length) so as to prevent it from being lifted at that point in order to attempt breaking in.
Returning now to the constructional details of the above mentioned parts, the first contact element comprises a body 10 having one end hinged, at X, to the fork 15 of the first slider 8, and a contact portion or head 18 connected as one to the hinged end by means of an arm 19.
The head 18 is suitably shaped, that is to say, provided with a cam-like profile divided into a first, arcuate front stretch 18a adapted to permit contact with the drive means 11 and lifting of the first element 10, and a second straight stretch 18b for stable positioning with the top end of the drive means 11, after lifting, and when the sash 3 is in the stable, lowered configuration (see
On the connecting arm 19 there is a pin 20 protruding downwardly and adapted to act as a limit stop element in the lowered, non-operating configuration of the first element 10 created by contact of the head 18 with a profile 2p inside the upper horizontal member 2b of the fixed frame 2. This contact occurs when the sash 3 changes from the lowered, closed configuration to the raised, open configuration and the head 18 moves away from drive and positioning means 11 thanks to the movement of the slider 8 connected to the operating means 7 (see
That is because the head 18 has a third, straight stretch 18c parallel to the second stretch 18b at the top surface of it that is designed to come into contact with the internal profile 2p of the upper horizontal member 2b during lifting of the sash 3.
The drive and positioning means comprise a fixed block 11 provided with a bottom portion that can be stably associated with the groove C (passing through the slot 14), and a top portion 11a in the form of a prismatic body.
The prismatic body 1 la has an inclined surface 11b designed to come into contact with the first contact element 10 (and, more specifically, the first stretch 18a of the head 18 and then the second stretch 18b) in such a way as to lift and support it upon movement of the first slider 8 as a result of the sash 3 moving to the lowered, closed configuration.
The contact element 10 is stabilized in the raised position by the stable contact of the second stretch 18b with an upper straight section of the prismatic body 11 (see
During assembly of the operating means 7 (and when at least two sliders 8, 8′ are fitted), the second slider 8′ is placed in the groove C of the upper horizontal member 9 after being coupled to the rod 21 which is in turn coupled to the other end of the slider 8 as the latter slides in the groove C (see arrow F13,
Before the first slider 8 is all the way inside the groove, it is coupled to the rod 22 so that the first slider 8 itself can be connected to the right-angle drive 13.
Once the sliders 8, 8′ and the right-angle drive 13 are in place, the latter is fastened at the corner between the upper horizontal member 9 and the vertical member 12 of the sash 3. This is done by connecting the right-angle drive 13 to the other operating means 7 located in the part of the groove C in the vertical member 12.
Next, the respective prismatic bodies 11 are positioned in and fastened to the groove C through the corresponding slots 14 in the sliders 8, 8′.
At this point, the sash 3 can be mounted on the fixed frame 2 while keeping the contact elements 10, 10′ in a lowered position (see
After mounting the sash 3, in the open configuration, the sash 3 itself can be moved to the closed configuration by turning the handle 6 to activate the operating means 7 so as to lower the sash 3 (see arrow F3,
At this stage, the translational motion of the rod segments causes the sliders 8, 8′ to slide, too (through the right-angle drive 13) thereby making the contact elements 10, 10′ move towards and abut against the prismatic bodies 11, 11′ (arrow F16),
This in turn raises the heads 18 (arrow F10) and causes them to stabilize themselves at the position shown in
During opening, on the other hand, the movement of the operating means 7 to allow the sash to be lifted and opened (arrow F2) causes the sliders 8, 8′ to slide in the opposite direction, moving the contact elements 10, 10′ away from the bodies 11, 11′ and, when the sash 3 is lifted (arrow F2) enables the contact elements 10, 10′ (free to rotate, see arrow F10,
A door/window made in this way thus achieves the above mentioned aims thanks to the presence of anti-lifting plugs mounted on the sash and adaptable to the different configurations of the sash in such a way as not to interfere with the movement of the sash but making the sash extremely secure when in the closed configuration.
The anti-lifting plugs are structured in such a way as to avoid the need to modify the general structure of traditional doors/windows of this type, especially of the sash, since the plugs use the grooves already present and the movements of the operating means which are also part of traditional doors/windows: this also advantageously translates as economic savings in terms of a lower overall cost of the door/window.
The invention described above is susceptible of industrial application and may be modified and adapted in several ways without thereby departing from the scope of the inventive concept. Moreover, all the details of the invention may be substituted by technically equivalent elements.
Number | Date | Country | Kind |
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BO2008A000381 | Jun 2008 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2009/052554 | 6/16/2009 | WO | 00 | 12/2/2010 |