The present invention relates generally to a position-fixing system, and more particularly to a position-fixing system adapted to fix a position of a covering material of a window covering.
A conventional cordless window covering, e.g., a cordless roller shade, includes a roller and a weighing member. The roller is installed to a bracket and capable of reeling a covering material in and out. The weighing member is connected to a bottom of the covering material so that the covering material is easy to manipulate and to counterbalance. The weighing member can be pulled downward to pull out the covering material correspondingly. As soon as the weighing member is freed from manipulation at any position, the covering material stays at a static limited state because of the effect of a brake mechanism which can counter a rewinding force generated by a spring mechanism. To retract the covering material, the weighing member has to be pulled downward first to disrupt the limited state of the covering material. And then, by letting go of the weighing member, the rewinding force of the spring mechanism takes over, driving the roller to roll up the covering material.
However, conventional brake mechanisms have complex structures and high cost. For example, the laborsaving bead-chain mechanism disclosed in Taiwan Utility Patent No. TWM272484 and the self-locking type sun-shading roller shutter device disclosed in China Utility Patent Application No. CN03229187 both have such disadvantages. Furthermore, after prolonged use, the components involved in a conventional brake mechanism to provide the braking effect are likely to wear out, leading to an inaccurate position-fixing effect. To provide the rewinding force as sufficient as possible, conventional cordless window coverings have to be applied with torsion springs with large torque, which requires higher manufacturing costs. In addition, since the weighing member has to be pulled downward first to disrupt the limited state of the covering material before rolling up the covering material, it would be inconvenient when there is no room for such operation, e.g., when the weighing member is already immediately adjacent to a bottom edge of a window frame as the covering material is fully spread out.
For above reasons, a position-fixing system which could be widely applied to various types of window coverings is provided. The position-fixing system is easy to operate, and is reliable in-fixing the position of a covering material.
In one aspect of the invention, a position-fixing system is provided, which is applicable to a window covering including a covering material, a shaft, and a bracket. The shaft is pivotally connected to the bracket, and the covering material has an end attached to the shaft so that the covering material is adapted to be spread out from the shaft or rolled up around the shaft. The position-fixing system includes a pole, a guiding member, and a movable member. The pole is mounted to the bracket in an immovable manner and is defined to have an extension axis collinear with a central axis thereof. The guiding member is disposed in the shaft in a manner that the guiding member rotates along with the shaft. The guiding member includes a guiding base spaced from the pole, wherein the guiding base is defined to have a principal axis passing therethrough. The principal axis of the guiding base and the extension axis of the pole extend in a same direction and are parallel to each other; the guiding base has a retaining face provided on a side thereof, and the retaining face and the principal axis are non-coplanar. The movable member fits around the pole and is arranged between the guiding base and the pole. The movable member is adapted to be driven by the rotation of the shaft to rotate relative to the pole. When the covering material is operated to be spread out or rolled up, the movable member and the guiding member are driven by the rotation of the shaft to rotate about the pole, and the movable member travels in a reciprocating manner along the pole and the guiding base; when the movable member is being moved, the movable member remains in contact with the pole as being guided by the retaining face to create a friction.
In one aspect of the invention, a position-fixing system is further provided, which is applicable to a window covering including a covering material, a shaft, and a bracket. The shaft is pivotally connected to the bracket, and the covering material has an end attached to the shaft so that the covering material is adapted to be spread out from the shaft or rolled up around the shaft. The position-fixing system includes a pole, a guiding member, and a movable member. The pole is mounted to the bracket in an immovable manner and is defined to have an extension axis collinear with a central axis thereof. The guiding member is adjacent to the pole and is adapted to be driven by the rotation of the shaft. The movable member fits around the pole and is arranged between the guiding member and the pole. The movable member is adapted to be driven by the rotation of the shaft. When the covering material is operated to be spread out or rolled up, the movable member and the guiding member are actuated by the rotation of the shaft to rotate about the pole, and the movable member travels along the pole and the guiding member in a reciprocating manner. A friction is created between the movable member and the pole when the movable member is being moved, for the movable member is guided by the guiding member to keep in contact with the pole.
With the aforementioned design of the position-fixing system compatible with window coverings, there would be a friction provided between the movable member and the pole, stopping the covering material at the instant position when the operation ends. These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
The present invention will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
A window covering 10 applied with a position-fixing system of the present invention is illustrated in
The position-fixing system 20 of the first embodiment includes a pole 22, a guiding member 24, and a movable member 26. The position-fixing system 20 is installed in the window covering 10. The pole 22 is mounted to one of the brackets 16 in an immovable manner so as to stay fixed relative to the window covering 10, and the guiding member 24 is adjacent to the pole 22. The pole 22 includes a body 222, a threaded section 224, a first stopper 226, and a second stopper 228. The body 222 is a long rod, and is defined to have an extension axis L collinear to a central axis of the pole 22. The threaded section 224 is formed around the body 222, and the first stopper 226 and the second stopper 228 are respectively adjacent to two ends of the threaded section 224. The guiding member 24 includes a guiding base 242, a first plank 244, and a second plank 246. The guiding base 242 has a retaining face 2422, and is defined to have a principal axis 2424 passing therethrough, wherein the principal axis 2424 extends in the same direction with the extension axis L of the body 222, and is parallel to the extension axis L. A first end 2424a and a second end 2424b of the principal axis 2424 are at where the first plank 244 and the second plank 246 joint the guiding base 242, respectively. The first plank 244 and the second plank 246 have a first notch 244a and a second notch 246a respectively. The first and second notches 244a, 246a fit the body 222 of the pole 22 so that the first and second planks 244, 246 of the guiding member 24 are capable of supporting the guiding base 242. Contours of the first and second notches 244a, 246a are greater than an outer diameter of the body 222 of the pole 22; the first and second planks 244, 246 are rotatable about the body 222 of the pole 22 thereby. The first stopper 226 corresponding to the first notch 244a has a contour greater than that of the first notch 244a, and the second stopper 228 corresponding to the second notch 246a has a contour greater than that of the second notch 246a. In this way, the guiding base 242 of the guiding member 24 is restrained within a segment corresponding to the retaining face 2422 thereof and the threaded section 224. For clarity, the phrase “principle axis” may be regarded as the phrase “imaginary line” throughout the whole specification of the present application.
The movable member 26 is approximately annular, and fits around the threaded section 224 of the pole 22 between the pole 22 and the guiding member 24. To match each other, the interior wall of the shaft 14 and an exterior contour of the movable member 26 are designed to have a guiding slot and a guiding lump in a complementary manner. The guiding member 24 is designed to correspond to the exterior contour of the movable member 26 as well. When the shaft 14 rotates, the movable member 26 and the guiding member 24 are driven by the rotation of the shaft 14 to rotate synchronously in the same direction. The movable member 26 is rotatable about the pole 22, and is adapted to travel in a reciprocating manner both along the threaded section 224 of the pole 22 and the guiding base 242 of the guiding member 24. To simplify the arrangement, the position-fixing system 20 of the current embodiment is disposed inside the shaft 14, and the pole 22 and the shaft 14 are arranged in a collinear manner; however, such arrangement is not a limitation of the present invention. In practice, the position-fixing system 20 can be also installed outside of the shaft 14 to meet specific requirements, but is still drivable by the rotation of the shaft 14.
In the current embodiment, the movable member 26 includes a support portion 262 and an actuation assembly 264; the actuation assembly 264 includes an elastic member 2642 and an actuation portion 2644. The support portion 262 is annular and surrounds the threaded section 224. Therefore, a distance between the support portion 262 and the threaded section 224 of the pole 22 in a radial direction of the pole 22 is constant. The support portion 262 has a passage 2622 in the radial direction of the pole 22. The passage 2622 goes through an annular wall of the support portion 262 approximately in the radial direction of the pole 22, communicating the guiding base 242 of the guiding member 24 and the threaded section 224 of the pole 22. An end of the passage 2622 faces the retaining face 2422 of the guiding base 242. The elastic member 2642 and the actuation portion 2644 are received in the passage 2622 in a movable manner. The actuation portion 2644 is disposed between the elastic member 2642 and the retaining face 2422 of the guiding member 24, so that an end of the actuation portion 2644 keeps abutting against the retaining face 2422, while an opposite end of the actuation portion 2644 keeps abutting against the elastic member 2642. In addition, an end of the elastic member 2642 opposite to the actuation portion 2642 keeps abutting against the threaded section 224 of the pole 22, whereby to create a force which would push the actuation portion 2644 away from the pole 22, and a friction which would be applied onto the threaded section 224 of the pole 22 (the arrangements mentioned herein can be seen in
In the first embodiment, the state that the covering material 12 is retracted to the shaft 14, as depicted in
In the circumstances of the current embodiment, the window covering 10 can be operated to be lowered or raised by pulling down or pushing up the covering material 12. Once the operation of the covering material 12 stops, the covering material 12 could stop at its immediate position due to the friction created between the movable member 26 and the threaded section 224 of the pole 22.
A second embodiment of the present invention is illustrated in
The difference between the first and second embodiments is that, in the second embodiment, the retaining face 3422 of the guiding base 342 of the guiding member 34 inclines and approaches the threaded section 324 of the pole 32 in a direction from the first end 3424a to the second end 3424b along the principal axis 3424, which means a distance between the retaining face 3422 and the principal axis 3424 increases gradually in the direction from the first end 3424a to the second end 2424b along the principal axis 3424. In more details, the guiding base 342 is homogeneous and solid, wherein a lateral side thereof opposite to the retaining face 3422 approximately abuts against the interior wall of the shaft 14 of the window covering 10. The guiding base 342 is getting thicker as getting closer to the power mechanism 18, so that a distance between the retaining face 3422 of the guiding base 342 and the threaded section 324 of the pole 32 gradually decreases in a direction toward the power mechanism 18, wherein a thickness of the guiding base 342 is measured in the radial direction of the pole 32. In other words, a cross-sectional area of the guiding base 342 increases in a direction toward the power mechanism 18 along the principal axis 3424 (or we can say, in a direction along the extension axis L of the pole 322). The direction from the first end 3424a (or the first plank 344) to the second end 2424b (or the second plank 346) is also defined as a first direction D1, which means, the direction D1 is the direction that the cross-sectional area of the guiding base 342 increases.
In the current embodiment, the pole 32, the guiding member 34, the support portion 362, and the actuation portion 3644 are made of solid materials, which are not likely to deform, while the elastic member 2642 is made of resilient materials with inherent elasticity. As the thickness of the guiding base 342 gradually increases in the direction D1, the retaining face 3422 gradually approaches the pole 32. Because the actuation portion 3644 and the pole 32 are made of solid materials which are not deformable in response to the gradual increase of the thickness of the guiding base 342, they would transfer a gradually increasing suppression caused by the gradual increase of the thickness of the guiding base 342 to the elastic member 3642. The elastic member 3462, which is inherently elastic, would deform and react in response to the gradually increasing suppression. Therefore, a friction between the elastic member 3462 and the pole 32 would be created in response to the increasing thickness of the guiding base 342. In principle, the elastic member 3462 could be made of any materials or components with the properties of reversibility and compressibility, such as springs, rubber, or silicone.
In the current embodiment, the state when the covering material 12 is retracted to the shaft 14, as depicted in
As the covering material 12 extends, the force driving the shaft 14 to rotate provided by the covering material 12 would become stronger. Although the rewinding energy is stored by the power spring 184 of the power mechanism 18, it is actually not sufficient to counterbalance the force provided by the covering material 12 for driving the shaft 14. The friction between the elastic member 3642 and the threaded section 324 in these embodiments of the present invention would gradually increase to help the power spring 184 of the power mechanism 18 to overcome the gradually increasing force caused by the gradual expansion of the covering material 12, whereby to achieve the purpose of precise fixing the position of the covering material 12. The same purpose could be also achieved in the situation when the covering material 12 is being raised.
A third embodiment of the present invention is illustrated in
The movable member 46, similar to those of the prior embodiments, is approximately annular, and includes a support portion 462 and an actuation assembly 464. The actuation assembly 464 is received in a passage 4622 of the support portion 462 in a movable manner, and includes an elastic member 4642 and an actuation portion 4644. The actuation portion 4644 is disposed between the elastic member 4642 and the retaining face 4422 of the guiding base 442, and the retaining face 4422 keeps abutting against an end of the actuation portion 4644. An opposite end of the actuation portion 4644 keeps abutting against the elastic member 4642, and an end of the elastic member 4642 opposite to the actuation portion 4642 keeps abutting against the threaded section 424 of the pole 42 for creating a force to push the actuation portion 4644 away from the pole 42 and, at the same time, a friction between the elastic member 4642 and the threaded section 424.
The state when the covering material 12 retracted to the shaft 14 is, again, defined as an initial state. The movable member 46 is approximately adjacent to the first plank 444, and corresponds to the first end 4424a of the principal axis 4424 of the guiding member of the 44, as illustrated in
A fourth embodiment of the present invention is illustrated in
The movable member 56 is approximately annular, and fits around the threaded section 524 of the pole 52, arranged between the pole 52 and the guiding base 542. The movable member 56 includes a support portion 562 and an actuation assembly 564, wherein the actuation assembly 564 includes an elastic member 5642 and an actuation portion 5644. The difference between the current embodiment and the prior embodiments is that, in the current embodiment, the number of the actuation assemblies 564 is two, and the two actuation portions 5644 are pivotally connected to two lateral sides of the support portion 562, respectively. In this way, the two actuation portions 5644 could pivot relative to the support portion 562 and rotate slightly about the support portion 562, whereby the extent of the suppression between the two actuation portions 5644 and the support portion 562 could be adjusted. Herein we take one of the actuation portions 5644 and the corresponding elastic member 5642 as an example. An end of the elastic member 5642 is connected to a free end of the actuation portion 5644, which is opposite to the support portion 562, and an opposite end of the elastic member 5642 is movably connected to one of the retaining faces 5422, which is far away from the actuation portion 5644. More specifically, an end of the elastic member 5642 hooks to the slot 5422a of one of the retaining faces 542, and the opposite end of the elastic member 5642 goes across the guiding base 542 to be connected to a one of the actuation portions 5644 in a secured manner. In other words, two ends of the elastic member 5642 are connected to one of the actuation portions 5644 and the guiding base 542, respectively. Therefore, the elastic member 5642 would create a force for pulling the actuation portions 5644 to approach the threaded section 524 of the pole 52. When the movable member 56 is driven by the rotation of the shaft 14 to travel in the first direction D1, the elastic member 5642 would travel along the slots 5422a. As the retaining faces 5422 move away from the principal axis 5424, the width of the guiding base 542 increases, the elastic member 5642 would be stretched gradually, and the force pulling the actuation portions 5644 would increase. Therefore, the suppression onto the threaded section 524 by the actuation portions 5644 would increase, and the friction between the actuation portions 5644 and the threaded section 524 would increases as well.
The operation of the position-fixing system 50 when the covering material 12 is operated to be spread out or to be retracted is further explained below. The state when the covering material 12 is retracted to the shaft 14, as depicted in
As previously mentioned, during the moving of the movable member 56 in the first direction D1, the friction between the actuation portions 5644 and the threaded section 524 would increase. When the operation of pulling down the covering material 12 stops, the friction between the elastic member 5642 and the threaded section 524, the rewinding force of the power spring 184 of the power mechanism 18, and a force caused by the covering material 12 to rotate the shaft 14 would come to an equilibrium. Therefore, the covering material 12 could stay at where it is when the operation of the covering material 12 stops. When the covering material 12 is pushed upwards to be retracted, the rewinding force of the power spring 184 of the power mechanism 18 would drive the shaft 14 to retract the covering material 12, and the movable member 56 would start to rotate and to travel along the guiding base 542 in a direction opposite to the first direction D1, i.e., a direction that the retaining faces 5422 get closer to the principal axis 5424. Since the width of the guiding base 524 decreases, the elastic member 5642 across the guiding base 542 would gradually gather, and the force pulling the actuation portions 5644 would decrease. The suppression onto the threaded section 524 by the actuation portions 5644 would also decrease, and the friction between the actuation portions 5644 and the threaded section 524 would decrease as well. At the same time, the force caused by the covering material 12 to rotate the shaft 14 would decrease gradually. When the operation of pushing up the covering material 12 stops, the friction between the elastic member 5642 and the threaded section 524 of the pole 52, the rewinding force of the power spring 184 of the power mechanism 18, and the force provided by the covering material 12 to rotate the shaft 14 would come to an equilibrium. The covering material 12, again, could stay at where it is when the operation of the covering material 12 stops.
A fifth embodiment of the present invention is illustrated in
The number of the retaining faces 6422 of the guiding base 642 is two. The retaining faces 6422 are provided on two lateral sides of the principal axis 6424, and are arranged between the first end 6424a and the second end 6424b of the guiding base 642. Each retaining face 6422 has a slot 6422a. The retaining faces 6422 extend in the first direction D1, and incline outwardly to gradually bias away from the principal axis 6424. In other words, a width of the guiding base 642 increases in a direction towards the second end 6424b, which means, the length of the crossbars of the guiding base 642 increases in the first direction D1.
The movable member 66 is approximately annular, as mentioned in prior embodiments, and fits around the threaded section 624 of the pole 62, arranged between the pole 62 and the guiding base 642 without exceeding the first stopper 626. The movable member 66 includes a support portion 662 and an actuation assembly 664, and the assembly 664 includes an elastic member 6642 and an actuation portion 6644. The actuation portion 6644 is pivotally connected to the support portion 662 to pivot relative to the support portion 662 and to rotate slightly about the support portion 662, whereby the extent of the suppression between the actuation portion 6644 and the support portion 562 could be adjusted.
An end of the elastic member 6642 is connected to the actuation portion 6644, and an opposite end of the elastic member 6642 goes across the guiding base 642 to hook to the slot 6422a of one of the retaining faces 6422 in a slidable manner. The two ends of the elastic member 6642 pull the actuation portion 6644 and the guiding base 642 respectively, so that the elastic member 6642 provides a force pulling the actuation portion 6644 towards the threaded section 624. When the movable member 66 travels in the first direction D1, the elastic member 6642 travels along the corresponding slot 6422a. As the retaining faces 6422 depart away from the principal axis 6424, the elastic member 6642 is stretched gradually, and the force pulling the actuation portion 6644 would increase. As a result, the suppression onto the threaded section 624 by the actuation portion 6644 would increase, and the friction between the actuation portion 6644 and the threaded section 624 would increase as well.
The state when the covering material 12 is retracted to the shaft 14, as depicted in
During the moving of the movable member 66, the friction in response to the force would increase. When the operation of pulling down the covering material 12 stops, the friction between the elastic member 6642 and the threaded section 624, the rewinding force of the power spring 184 of the power mechanism 18, and a force caused by the covering material 12 to rotate the shaft 14 would come to an equilibrium. Therefore, the covering material 12 could stay at where it is when the operation of the covering material 12 stops. Conversely, when the covering material 12 is pushed upwards to be retracted, the rewinding force of the power spring 184 of the power mechanism 18 would drive the shaft 14 to retract the covering material 12, and the movable member 66 would start to rotate and to travel along the guiding base 642 in a direction opposite to the first direction D1, i.e., a direction that the retaining faces 6422 get closer to the principal axis 6424. The width of the guiding base 642 decreases in the direction opposite to the first direction D1, and the elastic member 6642 across the guiding base 642 would gradually gather, decreasing the force pulling the actuation portions 6644. The suppression onto the threaded section 624 by the actuation portions 6644 would decrease, and the friction between the actuation portions 6644 and the threaded section 624 would also decrease. At the same time, the force that caused by the covering material 12 to rotate the shaft 14 would decrease gradually. When the operation of pushing up the covering material 12 stops, the friction between the elastic member 6642 and the threaded section 624, the rewinding force of the power spring 184 of the power mechanism 18, and the force provided by the covering material 12 to rotate the shaft 14 would come to an equilibrium to stop the covering material 12 at where it is when the operation of the covering material 12 stops.
It is worth mentioning that, the position-fixing system compatible with the window covering disclosed in the present invention allows manipulation of the covering material for extension or retraction. The position-fixing system further provides a friction between the movable member and the threaded section of the pole for stopping the covering material at the immediate position once the manipulation stops. In addition, as the width or the thickness of the guiding base gradually varies in accordance with the traveling of the movable member along an extension axis of the pole, the status the movable member in relative to the retaining face of the guiding base would change, and the friction would vary in response to the changes of the status. Therefore, the friction would be sufficient as required to counterbalance the force that the covering material provides to drive the shaft and the rewinding force, whereby the position of the covering material 12 could be precisely fixed without having any excessive upward or downward movements.
It must be pointed out that the embodiments described above are only some preferred embodiments of the present invention. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present invention. Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
Number | Date | Country | Kind |
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201721053300.1 | Aug 2017 | CN | national |
201820385179.0 | Mar 2018 | CN | national |
Number | Name | Date | Kind |
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3965960 | Massey | Jun 1976 | A |
4429729 | Winslow | Feb 1984 | A |
5078198 | Tedeschi | Jan 1992 | A |
20190323285 | Wong | Oct 2019 | A1 |
Number | Date | Country | |
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20190063151 A1 | Feb 2019 | US |