RU2433240C1 - Self-lifting window closing facility - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: window closing facility comprises a driving device - a spring with a permanent coefficient of stiffness, which is adapted to apply a substantially permanent rotary force to the axis of the drive, a unit of cord winding, a pressing accessory. The unit of the cord winding is coaxially installed on the driving axis, comprising at least one winding drum, functionally joined with the second end of the cord for lifting and having a conical section, a rotary mounting element to move a window unit of cord winding sideways along the axis of the drive as the mounting element rotates to transform the rotary force along the axis of the drive into the lifting force to the cord for lifting, in which the force directed upwards is higher than the force directed downwards, applied with an element of a curtain and a lower guide along the whole range of opening and closing. The pressing accessory or a blocking element, is functionally connected to the axis and is adapted to unlock the drive axis in the required position.

EFFECT: invention will make it possible to prevent damage of a window closing facility.

20 cl, 23 dwg

Description

The present invention relates to window closing means that can be lifted without the need for force for either the adjusting mechanism or the window closing means itself as the window closing means opens. In particular, the present invention relates to window closing means having a control mechanism configured to apply an upward force on the curtain element and the lower guide, which is sufficient to lift the curtain element and the lower guide without additional effort exerted by the user during the lifting.

Window curtains and closing means are the basis of many applications and are used to regulate the amount of light entering the room and to provide aesthetic appeal to the decor. Such window blinds and closing means take many forms, including roller blinds, Roman blinds, lifting blinds and cellular curtains. Conventional cellular or pleated blinds use a cord, cord clamps or transmission mechanisms to raise, lower and place the closure in the required position. For window closers using a cord lock, the cords extend upward through the pleated fabric across the inside of the upper guide and exit through the locking mechanism. Other cellular curtains include a transmission mechanism and a continuous loop cord that is pulled by the user to raise and lower the window curtain. Roman blinds and lifting blinds also tend to include lifting cords that attach to the lower rail or lower rail.

There are some drawbacks to these projects. Cords present the potential risk of a child getting strangled or strangled with an external control cord. Cords also tend to distract from the aesthetics of the window closure in that they extend along the front surface of the window closure and, when the window shade is open, must either be wrapped in a hook or simply left on the floor. For window closers that use cord locks, the cords also undergo substantially abrasion due to friction with respect to surfaces, as a result of raising and lowering the closure.

Other window closers include conventional roller blinds that operate in the absence of a cord. These roller blinds include a coil spring retractor in combination with a clamping or locking mechanism mounted with a roller on which the curtain is twisted and assembled. In action, the roller blind is pulled down by the user to the desired location, where it is locked in place by a clamping or locking mechanism. To unlock and release the curtain so that it can be lifted, the user usually pulls the lower guide of the curtain toward him, lengthening the curtain enough to disengage the internal clamping or locking mechanism in it. When the clamping or locking mechanism is disengaged and the user releases the curtain, the curtain is retracted using a retractor driven by a torsion spring. Known roller blinds, however, are functional with a flat curtain material that rolls neatly into a limited location.

The mechanism used in such a roller blind is not compatible with other window closing means, such as cellular curtains, lifting blinds and Roman blinds. As the roller blinds rise, the size of the curtain to be lifted decreases so that the spring element of constant torsional force is able to apply the necessary winding or upward force over the entire opening range. In contrast, a similar lifting mechanism is usually unsuitable in cellular curtains, lifting blinds and Roman blinds. In these types of window closing means, the material of the curtain element is usually collected by the lifting lower element, such as the lower guide, and increasing weight values are collected on the lower element as the window closing means rises. The reason for this is that the material of the curtain or element of the curtain is more and more being folded onto the lower guide as the lower guide rises, which increases the load on the lifting mechanism.

In order to match the increasing weight, very strong torque springs are used to accommodate the maximum weight of the curtain. One drawback of this approach, however, is that the speed at which the window closure is retracted may be too fast and uncontrollable. One attempt to solve this problem is justified in US patent No. 6666252, issued in the name of Welfonder. This patent examines the use of a hydraulic brake to control the speed at which the lifting cords are pulled in throughout the lifting process. Another approach that was used is shown in US Pat. No. 6,056,036 to Todd, which uses a mechanical friction element for a constant slow retraction speed. One problem with this approach is that the spring applied causes stress, which makes it difficult for the user to overcome it when he tries to lower the curtain. Excessive pulling force developed by the user often leads to damage to the window closure.

As an alternative, springs with variable stiffness were used. Such variable stiffness springs are substantially more difficult to use and manufacture.

Therefore, there is a need for a window closing mechanism for window closing means, such as lifting blinds, mesh curtains and Roman curtains, which is self-lifting and solves the above problems.

The present invention relates to a self-lifting window closure and a regulating mechanism for window closing means. In particular, the window closing means is a self-rising window closing means that includes an upper guide, a curtain element such as a mesh panel, louvre plates or Roman curtain material, a lower guide, at least one lift cord, functionally attached to the first end to lower guide, and adjusting mechanism. The upper guide can determine the elongated groove, while the regulating mechanism is placed in it. In some embodiments, the control mechanism includes a drive axis and a drive device operably coupled to the drive axis. A drive device, which may be a spring with constant stiffness, provides a substantially constant rotational force on the drive axis.

At least one cord winding assembly is also mounted coaxially with respect to the drive axis. Typically, the number of nodes for winding the cord will be the same as the number of cords for lifting. However, in some cases, one node for winding the cord can be adapted to operate with multiple cords. The cord winding assembly includes at least one winding drum operably coupled to a second end of the lifting cord and having a tapered portion. The cord winding assembly also includes a mounting member for moving the cord winding assembly sideways along the axis of the drive while rotating the mounting member. In a preferred embodiment, the mounting member is a threaded tubular member associated with a winding drum. The cord winding assembly is adapted to convert rotational force on the drive axle into lifting force on a lifting cord, while the lifting force is greater than the total downward force exerted by the curtain element and the lower guide over the entire opening and closing range. In the present preferred embodiment, the cord winding assembly is rotationally fixed to the drive axis by a sleeve member adapted to engage the cord winding assembly and the drive axis. The sleeve element may be in a sliding relationship with the conical portion of the cord winding assembly.

The clamping device, or locking element, is also functionally connected to the drive axle and is adapted to unlock the drive axle in the required position. In a preferred embodiment, the clamping device comprises reciprocating means arranged coaxially with respect to the drive axis and movable between the unlocking position and the locking position, and a spring element connected to the reciprocating element and acting to either strengthen or loosen the element reciprocating movement on the drive axle. The reciprocating means is configured to cause the spring element to be clamped on the drive axis in the locked position to block rotation of the drive axis against the rotational force exerted by the drive device and to cause the spring element to loosen the drive axis in the unlocked position to allow rotation of the drive axis under the action of rotational force applied by the drive device.

The invention is illustrated in the drawings, where:

figure 1 is a perspective view, partially in section, of a preferred embodiment of a window covering means according to the present invention;

figure 2 is a perspective view with a spatial separation of the parts of the drive element of a single coil spring according to figure 1;

figure 3 is a side view of a drive element of a single coil spring;

Fig. 4 is a side sectional view of an alternative single coil spring drive member;

FIG. 5 is a side sectional view of a double coil spring drive member; FIG.

FIG. 6 is a side sectional view of an alternative dual coil spring drive member; FIG.

Fig.7 is a perspective view with a spatial separation of the parts of the node winding cord shown in Fig.1;

figa is a front view of the window closing means according to figure 1 in the closed position and with the upper guide in section;

Fig. 8B is a front view of the window closing means according to Fig. 1 in a partially open position and with a top guide in section;

figa is a perspective view of a preferred clamping device when the window closing means is in the fully raised position;

figv is a view in section of the clamping device according figa;

figa is a perspective view of the clamping device according figa, when the user pulls down the window closing means;

figv is a view in section of a clamping device according to figa;

figa is a perspective view of the clamping device according figa, when the user unlocks the window closing means;

11B is a sectional view of the jig according to FIG. 11A;

figa is a perspective view of the clamping device according to figa, when the user pulls down the window closing means to unlock the clamping device;

figv is a view in section of a clamping device according figa;

figa is a perspective view of the clamping device according to figa, when the window closing means independently rises;

figv is a view in section of the clamping device according figa;

Fig. 14 is a perspective view of an alternative embodiment of a window closing means according to the present invention with a brake element;

figa is a side view in section of the brake element according to fig.14, detached from one node of the cord winding;

FIG. 15B is a side cross-sectional view of the brake element of FIG. 14 interlocking one cord winding assembly; FIG. and

FIG. 15C is a side sectional view of the brake member of FIG. 14 when the window closing means is fully raised.

The invention disclosed below is valid for implementation in many different forms. The options shown in the drawings and described in detail here and below are preferred embodiments of the present invention. The present disclosure, however, is only an example of the primary principles and features of the present invention and does not limit the invention to exemplary embodiments.

1 shows an embodiment of a self-lifting window closing means 10 according to the present invention. An upper guide 12 is provided to define the groove. A pair of drive devices, such as spring devices 14 and 16, are coaxially mounted around the drive axis 18. Also, nodes 20 and 22 are installed on the drive axis 18 for winding the cord. Each of the cord winding units 20 and 22 includes a truncated cone-shaped winding drum 24 and 26 and a threaded tubular member 32 and 34, respectively. Lifting cords 28 and 30, which are shown as winding on the winding drums 24 and 26, are attached at the end of the winding drums 24 and 26. In this embodiment, the clamping device 36 is also provided and coaxially mounted on the drive axis 18. Each of these components in detail discussed below. Window closure means 10 further includes a curtain element, such as curtain material 38, and a lower element, such as a lower guide 40. The term “cord” as used may encompass a cord, strip, tape, rope or similar flexible elongated elements, which are suitable for supporting the suspended curtain element and which can be wound and unwound to unfold and retract the curtain element. A relatively short length of cord 42 can also be provided so that the user can pull down the window closing means and, as will be discussed in detail below, unlock the clamping device so that the window closing means will retract itself.

Figure 2 shows a preferred embodiment of the spring device 14. The spring device 14 comprises a spring housing 42, which is closed by a cover 48. A coil spring 46 and a spring axis 44 are fixed inside the housing 42, which is closed by a cover 48. The first end 50 of the coil spring 46 is attached to the axis 44 of the spring, which is coaxially connected to the drive axis 18 (figure 1). In this preferred embodiment, the coil spring is configured to provide sufficient rotational force to the drive axis 18 and winding reels 24 and 26 to lift the curtain element and the lower guide. Other alternative embodiments of spring devices are also possible, such as those shown in FIGS. 3-6.

For example, a suitable spring device 114, shown in FIG. 3, may include a twisted spring element 146 having a first end secured to a first spring axis 142 that attaches to a drive axis 18 of FIG. 1 and a second end, fixed with a second spring axis 144, which is offset from the first spring axis 142. The coiled spring 146 in a relaxed position can be initially wound around the axis 144 of the second spring. As the curtain element is pulled down, the coil spring 146 can be extended from the axis 144 of the second spring and progressively wrapped around the axis 142 of the first spring. This configuration of the spring element 114 may be suitable when the coil spring 146 used is longer to allow a longer range of placement of the curtain element.

Figure 4 shows another suitable spring device 214, which is similar to the embodiment shown in figure 3, except that the second end of the coil spring is not connected to any axis of the second spring. Instead, the coil spring 246 is wound around itself at its second end, while the first end 252 of the coil spring 246 is attached to a single spring axis 218 connected to the drive axis 18 shown in FIG. 1.

In addition, other suitable embodiments are depicted in FIGS. 5 and 6. In FIG. 5, the spring device 314 includes an assembly of two coil springs 346 and 348, which can be used to provide greater lift for the curtain element. This first coil spring 346 has its first end attached to the axis of the first spring 344, and the second coil spring 348 has its first end attached to the axis of the second spring 345. The second end of the first coil spring 346 and the second end of the second coil spring 348 are respectively connected to an axis 318 of a third spring located between the axles 344 and 345 of the first and second spring and attached to the drive axis 18. As the curtain element is pulled down, the coil springs 346 and 348 can, respectively, extend from the axis 344 and 345 of the first and second springs for the translational winding around the axis 318 of the third spring to apply increased lifting force to the drive axis 18. In FIG. 6, the illustrated embodiment is very similar to that of a cat 5, except that the two coil springs 446 and 448 that are wound on an axis 418 attached to the drive axis are not connected to the axes of the second spring. Although each of the shown embodiments uses a spring as a drive mechanism for the drive device, it should be understood that any suitable mechanism may be used to transmit rotational force to the drive axis.

Referring again to FIG. 1, the rotational force exerted on the drive axis 18 causes the cord winding units 20 and 22 to rotate and transmitted for the cords 28 and 30, which thereby lift the curtain element 38 vertically in the direction of the upper guide 12. Further details on a preferred embodiment of the cord winding assembly is provided by reference to FIG. 7.

The cord winding assembly 20 is mounted coaxially with the drive shaft 18, which extends through a fixed housing consisting of a frame 64 and a top cover 65. The cord winding assembly 20 includes a winding drum 24 and a rotational mounting member, such as a threaded tubular member 32, rigidly connected at the end of the winding drum 24. The cord winding assembly 20 is preferably mounted on the drive axis 18 by means of a sleeve element, such as an adapter 60, which is configured to transmit rotational motion between the axis 18 and the node 20 for winding the cord, while allowing translational movement between them. In some embodiments, the adapter 60 can be coaxially mounted inside the center hole of the winding drum 24 and includes a through hole for receiving the drive axis 18. To transmit rotational motion, while allowing uniform translational movement between the winding drum 24 and adapter 60, the peripheral surface of the adapter 60 may be provided with radial portions that come into contact with ribs protruding radially inward from the surface of the central hole winding about the drum 24. In addition, the threaded tubular element 32 engages with the gear rollers 66, which are rotationally mounted in the frame 64, and the bracket 68 is rigidly fixed in the upper guide 12. Thus, the rotational movements can be transmitted between the drive axis 18 and the node 20 for winding the cord, while uniform progressive movements with reduced friction forces between them are permissible. In addition, engagement by an adapter 60 and a threaded tubular member 32 allows for improved load bearing of suspended components, for example, a curtain member 38 and a lower guide 40.

The winding drum 24 is cone-shaped, preferably in the form of a truncated cone, and may include grooves or grooves to improve the grip of the cord 28 wound on the surface of the winding drum 24. The end of the lifting cord (not shown) is attached near the end 62 of the larger diameter of the winding drum 24 As the cord winding assembly 20 rotates and shifts in the direction of winding the lifting cord 28, the lifting cord is wrapped around increasingly narrower portions of the winding drum 24.

Referring to FIGS. 8A and 8B, the lifting action of a window closing means is shown. When the curtain element 38 is fully installed, as shown in FIG. 8A, the lifting cord 28 is fully extended from the wider portion of the winding drum 24. As the lower guide 40 rises under the elastic force of the spring devices 14 and 16, as shown in FIG. .8B, the threaded engagement between the threaded tubular member 32 and the rollers 66 causes the cord rotary winding device 20 to move sideways inside the upper guide 12 so that the lifting cord is wound along the winding drum 24 towards of the narrower end.

Since the rising lower guide 40 causes the curtain element 38 to fall and fold one above the other in it, the total weight lifted by the elastic force exerted by the spring devices 14 and 16 thus increases. The load on the spring devices is further described by reference to one of the spring devices. The load on one spring device 14 is obtained by the corresponding scale factor from the moment M to the drive axis 18, which can be approximated by the product between the suspended weight W, which includes the weight of the lower guide with the addition of the size of the curtain element 38 laid in it, and the radius R of the winding winding drum 24. As the lower guide 40 rises, W will increase and R will decrease, as the cord 28 for lifting is wound on more and more narrow cone-shaped sections an accurate drum 24 that slides with reduced frictional forces due to the adapter 60 and the threaded tubular member 32. Therefore, although the suspended weight W increases, the load M on one spring device 14 can be maintained at a level that varies slightly and can be surpassed by the spring 46 with constant stiffness (Fig. 2) for the complete raising of the lower guide 40 and the curtain element 38. In order to lower the window closing means, the user produces an approximately constant pulling force independently ie adjustment of window closing means. By means of the cord winding units 20 and 22, the spring devices 14 and 16, a constant force can thus be used accordingly to lift the load of the suspended weight W, which increases as it rises.

In some embodiments, such as the embodiment shown, the curtain element itself may have an effect on the total downward force or suspended weight. For example, if the curtain element is a cellular window closing means, a proper upward spring inclination relative to the material can serve to reduce the overall downward force. The full contribution of this spring bias varies depending on the extent to which the cellular window covering means is elongated.

As explained, as the window closing means opens, the total suspended weight increases and the total lifting force decreases. For this reason, the speed at which the window closing means rises decreases as it approaches the fully open position. Consequently, the disadvantage, usually embedded in a roller blind, is avoided, where the curtain retracts quickly and abruptly.

Figure 6 shows the fixture 36 provided for blocking the element of the curtain 38 and the lower guide 40 in the required position. The jig 36 is mounted coaxially with respect to the drive axis 18 and is configured to unlock the drive axis 18 when the user pulls the lower guide 40 down to stretch the curtain element 38 and to lock the drive axis 18 when the user releases the lower guide 40 to the desired height. When the user again slightly pulls the lower guide down, the clip disengages and allows the lower guide 40 to be lifted by the spring devices 14 and 16. FIGS. 9A and 9B show a clamping device 36 including a housing 70 that has fixed protrusions 72 and 74. It is envisaged a ring 76 rotating with a drive axle 18 that reciprocates axially along the drive axis 18. A reciprocating element 78 is coaxially mounted on top of the ring 76 and is, in addition, movable both rotationally and axially. A spring 80 having a first end 82 and a second end 84 is located between the ring 76 and the reciprocating element 78.

On figa and 9B depicts a clip when the window closing means 10 is in the fully raised position. The spring 80 is in a relaxed state with the second end 84 in abutting connection with the protrusion 74. As shown in FIGS. 10A and 10B, when the user pulls the lower guide (not shown) onto himself, there is a clockwise rotation (as shown) of the drive axis 18 and the ring 76 and causes the second end 84 of the spring 80 to disengage from the protrusion 74. The spring 80 is clamped on the ring 76 so that the rotation of the ring 76 is transmitted to the reciprocating element 78 by contact between the first end 82 of the spring 80 and the return element 78 with a reciprocating movement, which brings the reciprocating element 78 into focus with the protrusion 72. Since the reciprocating element 78 abuts the protrusion 72, the spring 80 loosens again and the drive shaft 18 can continue to rotate as the user further pulls the lower guide. Referring to figa and 11B, as the user releases the lower guide to the desired height, the spring 80 is clamped on the ring 76, and the drive axis 18, under the influence of the spring devices 14 and 16 (figure 1), rotates the element 78 with back - translational movement in the counterclockwise direction before it reaches the locked position, where the protrusion 72 abuts against the stopper 79 on the element 78 with reciprocating movement. In this locked position, the spring 80 is pressed to stop the rotation of the drive axle 18 against the lifting force exerted by the spring devices 14 and 16. Referring to FIGS. 12A and 12B, as the user pulls slightly downward toward the lower guide, the spring 80 is compressed and causes turning the drive axis 18 clockwise, and the ring 76 causes the reciprocating element 78 to disengage from the lock position to the output position. When the user releases the lower guide, as shown in FIGS. 13A and 13B, the spring devices 14 and 16 cause the drive axle 18 to rotate in a counterclockwise direction to engage the second end 84 of the spring 80 to engage the protrusion 74 and thereby loosen the spring 80, which allows the drive axis 18 to continue to rotate and fully open the window closing means.

An alternative embodiment of a window closing means according to the present invention is shown in FIG. In most aspects, this embodiment is the same as the embodiments described previously. The window shade 510 includes an upper guide 512 having a pair of spring devices 514 and 516 secured by a drive axis 518. Nodes 520 and 522 are also provided for winding the cord. Lift cords 528 and 530 pass through the curtain element 538 and are connected to the lower guide 540. At least one braking element 550 is additionally provided. The brake element 550 is capable of engaging with one cord assembly 522 to slow down the raising of the lower guide 540 when she will approach the upper guide.

A preferred embodiment of the braking member 520 is shown in FIGS. 15A-15C. In the position of FIG. 15A, the cord winding assembly 522 is disengaged from the braking member 550. As the cord winding assembly 522 wraps the cord 526, the cord winding assembly 522 also moves toward the braking member 550. Since the cord winding assembly 522 engages with the plate 552 of the braking member 550, as shown in FIG. 15B, the rotation of the cord winding unit 522 causes the plate 552 to rotate. The plate 552 is connected to an axial sleeve 554 that is in contact with the braking member, such as a viscous oil fluid, zhaschayasya within the cavity. The sleeve 554 is configured to make strong contact with the braking member to inhibit rotation of the cord winding assembly. For example, protrusions or ribs may be provided on the axial sleeve 554. The speed at which the lower guide is lifted by the spring devices 514 and 516 slows down as the lower guide reaches the upper guide so that the lower guide stops more smoothly when fully open.

The above descriptions should be taken as illustrative, but not limiting. Still other options within the scope of the idea and scope of the present invention will be readily apparent to those skilled in the art.

Claims (20)

1. Self-rising window closing means, comprising: an upper guide; bottom element; a curtain element suspended between the upper guide and the lower element; and a control mechanism mounted inside the groove of the upper guide, including: a drive axle; a drive device applying a rotational force to the drive axis; at least one cord winding assembly mounted on the drive axis and including a winding portion; at least one lift cord having a first end and a second end, wherein the first end is secured to the winding portion and the second end is connected to the lower element; and a clamping device connected to the drive axis, the clamping device having a locked position and an unlocked position, wherein the clamping device in a locked position blocks the rotation of the drive axis against the rotational force exerted by the drive device, and in the unlocked position, the clamping device unlocks and rotates the drive axis under the action of rotational force applied by the drive device, while the clamping device is made with the possibility switching from the locked position to the unlocked position by the rotational force applied to the drive shaft, which is opposite from the rotational force of the drive device. 2. The window closure according to claim 1, wherein the winding portion has a first end with a first diameter and decreases in diameter towards the second end with a second diameter smaller than the first diameter, wherein the cord winding assembly further includes a threaded a tubular member engaged with one or more gear rollers to axially move the cord winding assembly along the drive axis when the cord winding assembly rotates. 3. The window closing means according to claim 1, wherein the adjusting mechanism further comprises a brake element adapted to engage with a cord winding unit for braking the lifting movement of the lower guide towards the upper guide, wherein the brake element provides a counter-rotational force drive device, when the brake element engages with the node for winding the cord, and the rotational force of the drive device is greater than the counter-brake force of the element. 4. Window closing means according to claim 1, in which the node for winding the cord is fixed to the drive axis by an element of the sleeve, which is in sliding engagement with the plot for winding the node for winding the cord. 5. The window closing means according to claim 1, in which the clamping device comprises: a reciprocating element located coaxially with respect to the drive axis and movable between the unlocked position and the locked position; and a spring element attached to the reciprocating element and acting to clamp and loosen the clamping element with reciprocating movement on the drive axis; wherein the reciprocating means is arranged to clamp the spring element on the drive axis in the locked position to block the rotation of the drive axis against the rotational force exerted by the drive device, and to loosen the spring element on the drive axis in the unlocked position to allow the drive axis to rotate under the action rotational force exerted by the drive device. 6. Window closing means according to claim 5, in which the clamping device further comprises a ring fixed to the drive axis, and having a peripheral surface around which a spring element is mounted. 7. Window closing means according to claim 1, in which the drive device comprises a spring with constant stiffness. 8. Window closing means comprising: an upper guide;
a curtain element vertically suspended at the upper end from the upper guide; a lower element fixed to the lower end of the curtain element, wherein the lower element is suspended from the upper guide in the first position; and a regulating mechanism operably connected to the lower element by means of a lifting element, in which the regulating mechanism selectively clamps the spring element and lifts the lower element from the first position to the second position under the action of moving down the lower element from the first position sufficient to disengage the drive, and in which portions of the curtain element are folded onto the lower element as the lower element rises. 9. The window closing means of claim 8, in which the lifting element is a cord, and the regulatory mechanism includes: a drive axis; a cord winding assembly connected to the lower element by a cord; and a control device, which is a clamping device, configured to block the rotation of the node for winding the cord in the first direction to raise the lower element when the lower element is in the first position, and to unlock the rotation of the node for winding the cord in the first direction under the action of moving down the lower element from first position. 10. The window closing means according to claim 9, in which the drive device comprises a spring element that constantly applies elastic force to rotate the node for winding the cord in the first direction, which wraps the cord element. 11. The window closing means of claim 9, wherein the clamping device rotates the cord winding assembly in a second direction to unwind the cord member when a pulling force is applied to the bottom member. 12. Window closing means according to claim 9, in which the clamping device and the node for winding the cord are connected to the drive axis. 13. Window closing means according to item 12, in which the drive device is configured to apply a rotational force to the drive axis. 14. The window closing means of claim 12, wherein the drive device generates rotational force selectively converted by the drive axis and the cord winding unit into the lifting force by the lifting member for lifting the lower member from the first position to the second position and for folding the increasing portions of the member curtains on the bottom element; a clamping device having a locked position and an unlocked position, wherein the locked position of the clamping device blocks the rotation of the drive axis against the rotational force, and the unlocked position of the clamping device rotates the drive axis under the action of the rotational force; and
the clamping device is driven from the locked position to the unlocked position by applying a second force opposite to the first direction. 15. Window closing means according to claim 8, in which the lifting element is a cord, and wherein the regulating mechanism comprises a drive device, a cord winding assembly connected to the lower element by the cord, and a brake element engaged with the cord winding assembly to inhibit the lifting movement of the lower element towards the upper guide, the brake element provides a counter force to the rotational force of the drive device when the brake element engages with the assembly for Amotki cord, and the rotational force of the drive device is greater than the reaction force of the brake element. 16. Window closing means according to 14, in which the lifting element contains at least one cord for lifting; at least one cord for lifting has a distal end connected with the lower element; the regulating mechanism further comprises a cord winding assembly configured to winding and unwinding at least one cord for lifting; the drive device constantly applies elastic force to rotate the node for winding the cord in the first direction, which wraps at least one cord for lifting; and the control device is a clamping device configured to selectively block the rotation of the cord winding assembly. 17. The window closing means according to clause 16, in which the clamping device rotates the node for winding the cord in the direction for unwinding at least one cord for lifting, when the downward force is applied to the lower element. 18. A control mechanism for a self-rising window closing means, a window closing means including an upper guide, a suspended curtain element and a lower guide, comprising: a drive axis; a drive device operably connected to the drive axle for applying a drive force to the drive axle; a first end of at least one lift cord operably connected to a lower rail; at least one cord winding assembly mounted on the drive axis, including a winding portion secured to the drive axis and including attaching to the second end of at least one lifting cord that is removed from the first end for in order to transmit at least a portion of the driving force to the first end of the lifting cord for lifting the lower guide and the portion of the curtain element that is folded onto the lower guide; and at least one node for winding the cord, further comprising an element of weakening efforts to reduce part of the driving force that is applied to the first end of the cord for lifting. 19. The control mechanism according to claim 18, wherein the force weakening element comprises a brake element adapted to engage at least a portion of at least one cord winding assembly for braking the lifting movement of the lower rail towards the upper rail , a brake element providing a reaction force against the driving force of the drive device when the brake element engages with at least a portion of at least one cord winding unit, and a driving force of the device the drive is greater than the reaction force of the brake element. 20. The control mechanism according to claim 19, further comprising a clamping device operatively connected to the drive axis, the clamping device configured to block the drive axis and block the rotation of the drive axis against the drive force applied by the drive device, while the clamping device is additionally made with the possibility of unlocking the drive axis under the action of the opposing force applied to the drive axis, which is opposite to the drive force of the device Drive-keeping.

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