The present invention relates to a smoke or fire barrier.
Smoke and fire barriers are intended to contain either smoke, fire or smoke and fire. In certain applications, fire barriers are required. In others the fire barrier must also stop smoke. Whereas in others still, the lower temperature task of restricting smoke from flowing throughout a building or other construction is adequate. Insofar as heat and smoke rises it may not be necessary for a smoke barrier to extend from a ceiling all the way to the floor. For instance at an atrium, a smoke curtain dropping from the ceilings around the atrium can contain the smoke from rising up the atrium. However, where the barrier is a fire barrier, it must extend all the way to the floor.
Wide barriers, that is with curtains having considerable lateral extent, the curtains often cannot be deployed from a single, unsupported roller, because the roller does not have sufficient stiffness to support the weight of the curtain. Intermediate supports or bearings can be provided for this. However this is not always possible.
It is known to solve this problem, by providing the barrier multiple rollers which are positioned either side by side or one above the other or in an arrangement intermediate these. The curtain deploys from the rollers in narrow portions, which overlap, one from one roller and the next from the other. The degree of overlap is an extent determined to suit the application. The overlapped curtain portions can then be, but are not necessarily, conjoined by a device such as a bottom bar to provide stability. The overlapped portions create the necessary seal because the fire condition will create a positive pressure which presses the overlaps together. The greater the pressure the greater the seal.
Overlapping types of curtains have advantages and disadvantages. A disadvantage is that if the overlap is small, each portion can deflect and open under air pressure. If the curtains are not conjoined the portions can open up more easily permitting smoke leakage.
The rollers, can be provided as single rollers or aligned sections of roller. They can have intermediate bearings between the narrow curtain portions or at least some of them.
This can give rise to another set of problems, in particular that as the curtain is deployed the diameter at which the narrow portions drop from the roller decreases with less curtain material remaining wound on the rollers, the individual portions move away from each other, with the potential for gaps to develop through which fire and/or smoke can escape.
Normally, the rollers are each provided with an internal motor, which has a reaction shaft extending from one end of the roller. The reaction shaft is fixed with respect to the structure in the which the barrier having the roller is installed and whereby the motor can turn the roller. The motor acts via a high reduction gearbox to generate sufficient torque to lift its curtain, with the gearbox and motor fast within the roller.
Please note that as used herein:
“curtain” means a textile screen that extends down from a deployment mechanism; “barrier” means the apparatus including both the curtain and the deployment mechanism;
“twin roller barrier” means a barrier in which the curtain is deployed by unwinding from two parallel rollers, narrow curtain portions arranged along the length of the rollers on alternate rollers with end margins overlapping opposite each other.
The object of the present invention is to provide an improved smoke or fire barrier of the twin roller type:
According to the invention there is provided a twin roller smoke or fire barrier including:
Whilst it can be envisaged that the supports include bearings for journalling the roller(s) on the movable supports, normally the rollers will include internal bearings with non-rotating shafts connectable to the supports extending from the rollers.
Either or both of the rollers can be movable in separation from the other.
In a simple form of the separation varying mechanism, the rollers are each suspended via support links from a common axis above and between them, the rollers being supported at the distal end of the links. Under their weight and that of the curtain, the rollers swing together against each other—or at least with the curtain margins swinging against each other.
In another simple form of the separation varying mechanism, the rollers are mounted in support blocks able to slide towards and apart from each other, the blocks being sprung loaded towards each other or mounted in inclined tracks so as to move together under gravity.
In one such embodiment, the mechanism includes a rack and a pinion. The pinion being attached to the motor reaction shaft and in mesh with a rack above it, whereby the motor's torque in lifting the curtain is reacted as a torque tending to move pinion and the roller away from the other roller.
In the preferred embodiment, a member in the separation varying mechanism is connected to the reaction shaft of a roller rotation motor and gearbox in a manner to cause reaction, the torque exerted by the motor to wind up the curtain, to operate the mechanism to increase separation of the rollers. Both rollers can be moved in this way or one only.
Insofar as driving the motor to wind the curtain down applies a reverse torque such as to move the rollers together, this could be relied upon. However, since the normal mode of operation is for gravity-fail-safe unwinding of the curtain, the rollers are preferably supported in such a manner that they swing together under gravity during unwinding. Alternatively, springs can be provided for this purpose.
It can be envisaged that the member to which the reaction shaft is connected could be one of the supports for the roller concerned. However in the preferred embodiments, the member is additional to the supports.
In one embodiment, the rollers are supported on depending links and reaction members are provided in an invert-V, the members being pivoted together at their common end and pivoted to the roller-journalling ends of the supports, with at least one of the reaction members being connected to the reaction shaft of one of the rollers. Whilst it can be envisaged that the supports and/or the invert-V members could be ganged together from end to end of the rollers, so that the reaction torque from a single motor could separate the rollers, in practice it is preferred for at least one of the rollers to be provided with (oppositely rotating) motors at both ends, whereby it is moved away from the other roller uniformly from end-to-end. To economise on motors and avoid the risk of the invert-V members passing over centre, one roller only is preferably allowed to move, with the other being restrained.
In accordance with a particularly preferred feature there is provided a twin roller smoke or fire barrier including:
The level to which the stabiliser will be deployed can be set in accordance with the smoke layer depth for the installation of the barrier.
The deployment means can comprise mechanical inter-connection with one or both of the main rollers for the curtain. Although the curtain extends from end to end of the rollers, it is envisaged that a drive could be taken from between curtain portions, where a curtain portion is present on the opposite roller. Such arrangement may be possible at a roller end. Mechanical interconnection is also possible by providing tapes for supporting the curtain stabiliser wound on smaller or differing diameter lengths of the roller, whereby one roller revolution deploys the curtain down further that the stabiliser. In the preferred embodiment, the stabiliser is deployed via tapes wound on the same roller diameter as the curtain portions, but of limited length. When their full extent is unwound, continuing turning of the rollers to fully deploy the curtain results in the stabiliser being wound up again, to its use position.
Alternatively the deployment means can be an independent mechanism, operated in a gravity fail-safe manner as the main rollers. The rate of fall and of retrieval of the stabiliser can be arranged to be less than that of the curtain by suitable choice of the motors and their reduction gearboxes. Equally descent rate can be modified when using tapes on the main curtain rollers by providing differing diameters between the curtain portion sections of the rollers and the stabiliser tape sections. It is conceivable for the stabiliser to be fully retrieved prior to full retrieval of the curtain, to avoid the curtain lifting and possibly pulling through the stabiliser.
The deployed position of the stabiliser will normally be regulated by tapes, cords or the like with which it is retrieved.
Whilst normally the stabiliser will horizontal when deployed, it can be envisaged that one or other end could deploy further down to more closely control that side of the curtain, even to the extent of the stabiliser extend to the bottom of the deployed curtain at one side.
Nevertheless in a simple arrangement, it can be envisaged that the deployment of the stabiliser can be stopped by stops in guides for its ends; it can be deployed downwards on a bottom bar or the like of the curtain; and retrieved upwards by the bottom bar.
The stabiliser can be a pair of bars, loosely linked at either end by links passing from one side of the curtain to the other at its edges. Alternatively, it can be a pair of horizontal plates either loosely or rigidly interconnected, in the latter case by spacing members rigidly connected to the plates.
Alternatively to the bars or plates being linked or tied together, or indeed in addition thereto, they can be guided at their ends by guides extending down on either side of the fall of the curtain.
The bars or plates can abut the curtain directly, one or other abutting in accordance with pressure across the curtain moving it in one or other direction, the movement being in accordance with clearance to allow free vertical movement of the curtain with respect to the stabiliser on deployment.
Alternatively, abutting members can be provided, hinged or otherwise movably connected to the bars or plates with the abutting members normally resting against the curtain. Conveniently the abutting members extend up from their hinges. Abutting the members allows them to control the curtain portions more closely against crossing at their edges, but also allows bottom weights of the curtain to be drawn up between them.
To help understanding of the invention, specific embodiments thereof will now be described by way of example and with reference to the accompanying drawings, in which:
Referring to the drawings, a smoke curtain barrier 1 has two rollers 2,3. Each carries curtain portions 42 ,43, which have overlapping end margins 52,53, that is to say an end margin of a portion 42 overlaps with and abuts with or is close to an end margin of the next portion 43 along the length of the barrier. It should be noted that when the barrier is fully deployed the margins may not actually touch, but are close to each other and separated by an distance that is negligible in the context of smoke containment. Whilst such a distance will be known to the skilled reader, typically it is 5 mm.
The arrangement of the curtain portions, as they hang down from the rollers on deployment, is such that they overlap at the margins throughout the height of the drop of the curtain. The extent of the overlap—again known to the skilled reader and typically 100 mm with the portions being 1000 mm wide—is such that under normal circumstances the barrier will form a barrier to smoke. The arrangement of curtain portions across the width of the curtain provides the ability for people trapped the wrong side of the barrier to pass through the barrier between adjacent portions, which can be readily parted from each other. Such use can result in curtain portions becoming displaced and abutting end edge 62 to end edge 63 as shown in
The rollers are mounted in a head box 11, which has an opening 12 through which the curtain deploys. The top of the box is provided at both ends with brackets 14, from which depend supports 15,16. The first 15 of these, one at one end and the other at the other for the roller 2, are integral with the supports brackets 14. At one, idling, end of the roller, there is a single support 151, which has a square aperture 17 for the square end of the idling shaft 18 of the roller. A C-clip 19 retains the shaft in its aperture.
At a driving end of the roller, that is to say the end at which the roller has its internal motor and high reduction gearbox, the shaft would normally be held similarly in a square aperture for drive of the roller. In the arrangement of this embodiment, the driving shaft is allowed limited rotational freedom. Two supports 152,153 are provided. An outer one 152 of these is provided with an aperture 20 so shaped to allow the square 21 of the driving shaft 22 to rotate by 45°. An inner one 153 has a plain bore 23 supporting a plain portion 24 of the shaft. Again a clip 19 retains the shaft in position. Inwards of the inner support 153, a lever arm 25 is pinned to the shaft 22. When viewed from the end of the roller, the lever arm can turn 45° towards the other roller 3. It does this when the curtain is being wound up. The mechanics are explained more fully below. Suffice here to say that the shaft is free to do this with respect to the shaped aperture 20, which normally does not apply torque to the square of the shaft 22. A further lever arm 26 is pinned to the idling shaft 18. It exerts no torque and will be referred to as strut 26.
The other roller 3 is supported on two swinging supports 16, which are pivotally connected at their upper ends to the brackets 14. The idling and drive shafts 183, 223 are free to rotate in the lower ends of the supports 16. In other words, there is no rotational attachment between the shafts and the supports. On the other hand, the driving shaft 223 carries a lever arm 253 and the idler shaft 183 carries a lever arm 263. The distal ends of the lever arms, struts 25 & 263 and 26 and 253 are pivotally connected. It should be noted that the rollers 2,3 are symmetrical to the extent that their motors are at opposite ends and when viewed from respective ends, each is driven anti-clockwise for winding up of their curtain portions and by the same token, their curtain portions apply clockwise torque to them when they are being wound up. The non-driven ends of the rollers have anti-clockwise torque applied to them by their curtain portions.
With reference to
At the opposite end, as shown in
It should be noted that the motors will normally stop their drive of the curtain up into the head box when a closure plate at the foot of the curtain reaches the head box and causes their current to rise to a stall current level. This causes a conventional motor control circuit to switch of the motor current and apply a brake current. The motors incorporate brakes not shown, which (as will be known by the skilled reader) normally hold the rollers stationary. It should be noted that the rollers are held braked in their swung apart position. On release of the brakes, the weight of the bottom bar of the curtain and of additional weights in 29 in pockets 30, causes the curtain to deploy downwards.
It will be noted from
Should the rollers continue to rotate, under the weight of the curtain material only, not only will the curtain become slack leading to the possibility of bellying and smoke leakage at the margins, but also the curtain will hang directly from its points 33 of attachment to the rollers. These will rotate until they are at the bottom of the rollers. The distance D will then be unacceptably large. To guard against this, chordal pieces 35, that is pieces defined by a chord and the short circumference between the ends of the chord, are pivoted in slots 36 at each end of the rollers. The pivot points 37 are provided at the one end of the chordal pieces and stops 38 are provided so that the straight sides of the chordal pieces can extend radially outwards of the rollers in equivalent positions at both ends of the rollers. The slots are positioned so as to be covered by wound up curtain material, that is to say that as the first turn of the curtain material approaches the respective chordal members, it causes them to be pivoted inwards into their slots. Equally as they are exposed, they pivot out. Springs 39 are provided to assist this.
Resilient stops are provided in the form of springs 40 to abut the chordal members when they are extending directly downwards below the rollers. This arrangement stops the rollers in a position such that the curtain portions are hanging down directly from their points of minimum separation, defining the distance D. These points 41 are known as the “quarter to” and quarter past” points, referring to the them being at the 3 o'clock and 9 o'clock points of a clock face.
In order to enhance the smoke tightness of the curtain at the margins, they are provided with magnets 402 ,403 arranged North to South on opposite margins. They hold the margins together and are pulled apart when the curtain is wound up with the rollers parted from each other.
Turning now to
Referring to
The rollers are mounted in a head box 208, which has an opening 209 with a rebate 210. A curtain stabiliser 211 is wound up into the rebate in the
The stabiliser is supported by tapes 220 extending from the rollers 202, 203. These are shorter than the drop of the curtain. This results in the tapes being wound back up in the opposite sense during the final deployment of the curtain. In other words at the full extent of the tapes, a position to which the curtain and the stabiliser deploy together, the tapes arrest the stabiliser's descent and then are wound up on the opposite side of the rollers. This is shown in
In order for the tapes to descend vertically to the stabiliser, they are guided by rollers 221, mounted in the head box.
It will be apparent from
Number | Date | Country | Kind |
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0909837.7 | Jun 2009 | GB | national |
0909913.6 | Jun 2009 | GA | national |
0909914.4 | Jun 2009 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB2010/001112 | 6/8/2010 | WO | 00 | 2/6/2012 |