WO2008041097A2

WO2008041097A2 - Suspension cord winding device for a shutter

Info

Publication number: WO2008041097A2
Application number: PCT/IB2007/002901
Authority: WO
Inventors: Eric Lagarde; Norbert Dupielet
Original assignee: Somfy Sas
Priority date: 2006-10-05
Filing date: 2007-10-01
Publication date: 2008-04-10
Also published as: EP2076651A2; CN101523008A; WO2008041097A3; FR2906834B1; FR2906834A1

Abstract

The suspension cord (4) winding device (10) for a shutter comprises a winding drum (11) to which the end of at least one suspension cord is attached, said drum having on the outer surface of the drum a helical groove (11R) to house said suspension cord and a guide means (12) for positioning the cord in the groove during winding. It is characterized in that the cord is held in the groove by a locking means (13) connected to the drum.

Description

Curtain suspension cord winding device.

The invention relates to a suspension cord winding device comprising a winding drum on which is fixed the end of at least one suspension cord. A helical groove is disposed on the outer surface of the drum. A guiding means makes it possible to position the cord in the groove during winding.

Blinds, whether they be canvases, venetian blinds, pleated blinds or other, generally comprise two suspension cords, one end of which is fixed to the winding drum and the other end is fixed to the free end. of the awning. In order to ensure a uniform winding and unwinding of the awning, that is to say an equal descent and rise on both sides of the awning for reasons of aesthetics and mechanical reasons (risk of jamming), it is necessary to ensure a regular winding of the two suspension cords on the winding drums, in regular turns, without overlapping. For this purpose, it is known to animate the winding drum with a simultaneous translational movement to the rotational movement and amplitude such that this translation is at least equal to the value of the diameter of the bead per drum revolution. One solution, described in several patents and in particular in the application US 6,158,494 A1, is to wind the cord in a helical groove formed on the drum. The cord is then guided as desired when wrapped around the drum. During the descent, the weight of the load bar keeps the cord in the groove of the drum. However, in the event that the screen encounters an obstacle, the cord may leave the groove of the drum if it continues to rotate. By taking place inside the box, the cord can then overlap and cause the inconvenience mentioned above. This phenomenon is even more likely when the movement is motorized because the obstacle is not necessarily detected or "Seen" and therefore a stop order is not systematically executed. To overcome this problem, a solution is illustrated in DE 1 509 779, US 3,181, 595 and FR 1 286 899 where the cord is covered by a cover: a tube. This piece is necessarily long, cumbersome and expensive. On the other hand, the drum and hood turn relative to each other. Therefore, if there is too much play between these two parts, the cord can get caught in this space and block the device.

The object of the invention is to provide a blind suspension cord winding device remedying the disadvantages mentioned above and improving the blind suspension cord winding devices known from the prior art. In particular, the invention proposes a blind suspension cord winding device to avoid the phenomena of overlapping turns and locking of the winding device.

According to the invention, the blind suspension cord winding device is defined by claim 1.

Different embodiments of the device are defined by dependent claims 2 to 7.

The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings, in which: FIG. 1 is a representation of an installation comprising two winding devices according to the invention, FIG. 2 is a partial view of a first embodiment of a winding device according to the invention, FIG. 3 is a partial sectional view along line II of FIG. 2, FIG. 4 is a section of a helical groove of a second embodiment of a winding device according to the invention, FIG. 5 is a partial section of a winding drum forming part of a variant of the second embodiment of a winding device according to the invention, FIG. 6 is a partial view in half-section along the line III. FIG. 7 of a third embodiment of a winding device according to the invention, FIG. 7 is a partial sectional view along the line H-II of FIG. 6 of the third embodiment of FIG. a winding device according to the invention.

The winding cord 10 of the invention is intended to be integrated in an installation 1 as shown in FIG. 1. This installation can be a motorized venetian blind comprising a load bar 2 and orientable blades. 3. The load bar 2 is connected to the winding devices 10 by two cords 4. Each winding device 10 comprises a drum 11 having a helical groove in which is housed the corresponding bead 4 and a guide means 12 allowing position the cord in the groove. The two drums 11 are interconnected by a shaft 5. This shaft 5 is rotated by a drive means 6 which can be a manual control or a motor. Blade orientation means may also be provided. It can be independent of the winding device or be associated with it. Generally, the winding devices 10 and the driving means 6 are integrally arranged inside a box 7. Two kinematics are possible for the winding of the cord. In a first case, the guide means 12 is fixed and the drum 11, rotated by the shaft 5, is free in axial translation with respect to this shaft 5. The guide means 12 comprises a fixed shape complementary to the groove being housed in it. Thus, when the drum rotates, it moves axially in response to the groove on this fixed form. The second alternative reverses the kinematics. The guide means 12 becomes mobile in translation but locked in rotation while the drum 11 becomes fixed in translation but still rotated by the shaft 5. In this second alternative, to ensure that the ends of the cords suspending the blind move only vertically, one can provide a system for returning cords, using, for example, pulleys.

The principle of the invention is to provide in a groove of the drum a blocking means integral with the drum. This locking means makes it possible to deliberately hold the cord in the groove of the drum. In the case where the locking means exerts a direct force on the cord, this effort is controlled and determined. By "integral" is meant that any movement of the drum causes a movement of the locking means. The connection between the locking means and the drum is of the embedding type and is for example made by molding the drum with the locking means or by any other means for fixing the locking means on the drum. Thus, the locking means is integral with the drum permanently.

Figures 2 and 3 show in detail a first embodiment of the winding device according to the invention. The cord 4 is held in the groove 11 R by means of a helical spring 13 with a variable helix angle. Indeed, the portions of turns between which the bead must be stuck have a helix angle equal to or substantially equal to the angle of the groove. However, the complementary portions of the turns have a different helix angle so that the pitch of the spring is equal to the pitch of the groove. Preferably, the helix angle changes continuously along the spring. The spring is housed in a recess 11 E of the drum 11. The recess extends for example axially on the drum along the groove. The cord 4 is secured to the drum 11 on the side A by pinching effect of the cord between two successive turns of the spring. When the drum 11 rotates, the cord 4 wraps around it by placing itself in the groove 11 R. The spring 13 is dimensioned and positioned in the recess 11 E so that the cord 4 is clamped between two turns of the spring 13 when it passes through. The helical groove 11 R is discontinuous, interspersed with space corresponding to the recess 11 E. When the cord passes through this space, it is pinched by two turns of the spring 13 housed in this recess. Several conditions are thus necessary. The gap between two successive turns is smaller than the diameter of the cord. The pitch of the helix of the groove is equal to or is a multiple of the pitch of the spring. Thus, if the ratio between the pitch of the helix of the groove and the pitch of the spring helix is n, the bead will jam in the spring every n turns of the spring. The outer radius of the spring R13 added to the spacing E between the drum 11 and the spring 13 is preferably greater than or equal to the outside radius of winding of the cord Re4. Preferably, means are provided to prevent rotation of the spring relative to its axis relative to the drum. Other springs may be disposed on the periphery of the drum to increase the holding of the cord. With this type of design, the spring is interchangeable which allows to better control the clamping force and to wind cords of different diameters (with a suitable spring size). For example, an increase in the diameter of the spring wire increases the pinch force, the gap between two successive spring turns being decreased and the stiffness of the wire being increased. Alternatively, the spring may be of the helical type with a constant helix angle. In this case, the helix angle of the spring is different from that of the groove and, in addition to the wedging effect between the turns of the spring, there is a baffle effect when the cord goes from the groove to the spring and or from the spring to the groove.

Figure 4 shows a second embodiment of the winding device. The cord 4 is trapped in a helical groove 11 R '. In this embodiment, the walls 20 of the section of the groove are closed so that the cord can not leave the section without effort. The walls 20 are closed by the presence at their outer ends of two extensions 21 extending axially. The opening O of the groove defined by the distance between two extensions 21 of the groove is smaller than the diameter D4 of the bead. These extensions 21 may be continuous throughout the groove or discontinuous, on defined areas, every half-turns, for example.

The section can be closed permanently or closed once the cord 4 is in the section, zipper type system.

Such a variant is described with reference to FIG. 5. In this variant, the drum 11 has a helix 40 with an L section. This helix can be continuous or discontinuous. The turns or portions of turn are connected to the hub of the drum 11 by hinges 41. They are bistable. In FIG. 5, the two portions shown on the left occupy a first stable position C and the two portions represented on the right occupy a second stable position D. Means (not shown) make it possible to tilt the portions between the two positions over the rotation of the drum. The winding groove of the bead is formed by the gap between the turns of the propeller 40. The gap between two turns does not occupy the same stable position is much greater than that existing between two turns occupying stable positions D. Thus, the bead can be retained between the different turns occupying the position D and can leave or come to wind without stress on the drum at the level of interstice separating two turns not occupying the same position. In this variant, there is no need to deform the drum to introduce the cord into the groove.

In the second embodiment, the blocking means can only prevent the bead from coming out of the groove. The cord is, in this case, free movement within the section of the groove which allows, with a suitable section, to equip the device cords of different sizes.

A third embodiment of the winding device is shown in Figures 6 and 7. The bead is pinched by clamping between walls 11 P1, 11 P2 deformable side of a groove 11 R ".When winding, the cord 4 is located in the groove 11 R ", as described in the first embodiment. By positioning in the groove 1 R ", the cord will deform the side walls 11 P1, 11 P2 of the groove until the cord is pressed against a stop, for example a rib 11 N. The winding is regular , the inner winding diameter is constant and corresponds to the Rb4 dimension of the abutment.The deformed walls apply, in return, efforts on the bead 4 which, taking into account the coefficient of friction at the cord-wall interface, prevents the cord out of the groove 11 R "as a radial force of a certain intensity is not achieved. In order for the force exerted on the bead to be substantially constant all along the groove 11 R ", an interstitial space 11 E1 is provided between two consecutive walls The side walls 11 P1 and 11 P2 deform in the interstitial space by the action of the cord.This deformation does not affect the pressure exerted on the cord in other sections of the groove. It is preferable that the deformation of these walls is elastic. With this embodiment, during the unfolding of the cord, the nip allows it to push it outside the box, that is to say, in the box, the cord remains in the groove section and then leaves the section at the guiding means. The risk of overlap is thus reduced. The advantage of a continuous pinch is the absence of loose parts in the box. The risk of overlap is therefore non-existent. On the other hand, in this embodiment, the winding diameter of the bead is constant, which is essential to maintain the horizontality of a load bar moved by identical drums.

In addition, by acting on the elasticity of the side walls and the interstitial space, such a drum allows to wind cords of different sizes. Preferably, the groove is in the shape of a "U". By "U" is meant a section having two side walls for applying pressure on the cord, the other sides may take different forms.

Thus, the invention provides a device for holding the cord in the groove of the drum during a maneuvering the blind with a locking means which prevents the cord from leaving the section of the groove of the drum. This means being integral with the drum, the risk of blocking the device is then reduced.

As seen above, the cord can be partially held, that is to say it is not maintained continuously along the groove. One advantage may be the simplification of the realization of the drum. In particular in the case of the first two embodiments, it would be preferable for the locking means to be arranged every U-turns, to facilitate the demolding of a possible drum made of plastic.

For the purposes of the present application, a standard helical groove provided in a winding drum and in which the bead would accidentally jam is obviously not a locking means integral with the drum.

Claims

Claims:

A blind suspension cord winding device (10) comprising: a winding drum (11) to which is attached the end of at least one suspension cord, said drum having a helical groove (11 R, 11 R ', 11 R ") disposed on the outer surface of the drum and intended to receive said suspension cord and - guiding means (12) for positioning the cord in the groove during winding, characterized in that the cord is held in the groove by a locking means (13; 21; 11 P1, 11 P2) integral with the drum.

2. Device according to claim 1, characterized in that the maintenance of the cord is obtained by pinching the cord.

3. Device according to claim 1, characterized in that the cord is free movement within the groove.

4. Device according to one of the preceding claims, characterized in that the locking means extends discontinuously along the groove.

5. Device according to claim 4, characterized in that the locking means is constituted by at least one helical spring (13), housed in the drum and whose pitch is substantially equal to the pitch of the helical groove (11 R) .

6. Device according to one of claims 1 or 2, characterized in that the locking means exerts a substantially uniform continuous pressure on each turn of the coiled cord.

7. Device according to claim 6, characterized in that the locking means comprises side walls of the groove, the section of the groove being in the form of a "U", a gap separating two consecutive sections located at a spacing interval .