The present invention relates to a handle and brake arrangement for a covering for architectural openings.
In typical prior art arrangements, a handle may be attached to a rail by snapping the handle into a complementary contour on the rail or by using bolts, screws or other threaded fasteners. The snap-on method often is not secure and may be aesthetically objectionable. The threaded fasteners can fail due to stripped threads, can be unsightly, or may involve the use of additional parts and labor in order to conceal the fastener.
The present invention provides a simple, secure, inexpensive, hidden, and relatively tamper-proof connection arrangement for securing the handle to the rail. In one embodiment the handle is secured to the rail via screws, using a skewed approach angle. The handle may be used not only to grasp the rail, but it also may provide a convenient mechanism to engage or disengage a brake in the rail.
In this embodiment, the spring motor 114 is underpowered such that it is unable to raise the shade 104 alone and needs additional input (referred to as a catalytic force) from the user to accomplish that task. This particular spring motor 114 also is unable to hold the bottom rail 102 in place once it is released by the user. The weight of the bottom rail 102 (together with the components found in the bottom rail 102 and the weight of the shade material) overwhelms the force provided by the spring motor 114 such that the bottom rail 102 will continue to drop once released by the user unless it is stopped by other means. To stop the bottom rail from dropping, a brake 116 is functionally connected to the lift rod 112 and to the bottom rail 102 to stop the lift rod 112 from rotating in at least one direction relative to the bottom rail 102, as explained in more detail later.
The handle 118 includes an actuator button 120 which, when depressed by the user, releases the brake 116, which allows rotation of the lift rod 112 in both clockwise and counterclockwise directions, as explained in more detail later.
The brake 116 can be mounted anywhere along the lift rod 112 and does not have to be precisely located relative to the handle 118 in order for the actuator button 120 to function to release the brake 116. This is advantageous, as it permits the handle to be secured to the rail 102 from inside the rail with the brake 116 out of the way, and then permits the brake 116 to be slid along the lift rod 112 into a position that is generally opposite the handle 118, without having to worry about the precise location of the brake 116.
As shown in
The slide element 156 has a contact plate 124, which is pushed against by the actuator in the handle 118, in a direction opposite to the braking direction, in order to disengage the brake. The slide element 156 is received in the housing base 154, with the contact plate 124 of the slide element 156 projecting through the opening 168 in the housing 154. The slide element 156 is guided by the housing base 154 so its movement is restricted to forward and backward movement in the direction of the arrow 188 relative to the housing base 154. Shoulders 190, 192 on the slide element 156 limit the movement of the slide element 156 in the forward direction as they impact the front wall 166 of the housing 154. As indicated above, the coil spring 158 biases the slide element 156 in the forward direction (which as explained later, is the braked position). The rear wall 194 of the slide element 156 defines a left-to-right directed ridge 196, which extends parallel to the front and rear walls 124, 194 of the slide element 156 and parallel to the lift rod 112.
The splined sleeve 160 is a generally cylindrical body defining a hollow through shaft 198 having a non-circular profile. In this particular embodiment, it has a “V” projection profile. The lift rod 112 (See
The splined sleeve 160 also defines a plurality of radially extending splines 200. The ends of the splined sleeve 160 define smooth stub shafts 201 which are rotationally supported on the “U”-shaped surfaces 176, 178 of the housing base 154. The slide element 156 has recessed arms 210, 212, which permit the slide element 156 to move forwardly and backwardly within the housing base 154 without interfering with the stub shafts 201.
As shown in
When the slide element 156 is pushed rearwardly by pushing against the contact plate 124, the ridge 196 moves out of engagement with the splined sleeve 160, allowing the splined sleeve 160, the lift rod 112, and the lift drums to rotate in order to raise or lower the movable rail 102.
A housing cover 162 snaps onto the housing base 154 to substantially enclose the slide element 156 and the coil spring 158 within the brake 116. As shown in
Alternate Embodiments of the Brake
This embodiment 116′ has the advantage that the brake 116′ need not be disengaged (unlocked) for rotation of the splined sleeve 160′ (and therefore rotation of the lift rod 112) in the counterclockwise direction (as seen from the vantage point of
As was the case for the previous embodiment 116′, this brake 116″ is used advantageously so that disengagement of the brake 116″ is only needed for lowering the shade 104 (See
As may be readily envisioned, the brake 116 may have other modifications as well. For instance, the splined sleeve 160 may be replaced by a smooth, non-splined cylinder, and the rear wall 194 of the slide element 156 and its corresponding ridge 196 may be replaced by a semicircular brake pad. The brake pad would be pressed against the cylinder by the biasing action of the spring to stop the rotation of the cylinder (and the rotation of the rod to which the cylinder is keyed). Pressing on the contact plate of the brake against the biasing force of the spring moves the brake pad away from the cylinder, allowing the cylinder and the lift rod to rotate in either direction.
Referring now to
The actuator button 120 is received in an opening 152 in the handle 118. (See
The finger 148 on the actuator button 120 abuts the ramped proximal end 144 of the actuator shaft 122. As the finger 148 moves downwardly and rearwardly, it pushes against the ramped proximal end 144 of the actuator shaft 122, which displaces the actuator shaft 122 rearwardly so the blunt distal end 142 pushes the contact plate 124 of the brake 116 rearwardly to disengage the brake 116.
In addition, as the finger 148 pushes rearwardly on the ramped proximal end 144 of the actuator shaft 122, it also moves downwardly along the ramped surface 144 of the actuator shaft 122. As a result, as the finger 148 pushes downwardly, it also pushes on a progressively more forwardly portion of the ramp on the ramped proximal end 144 of the actuator shaft 122. This results in an effective rearward motion of the actuator shaft 122 which is considerably larger than the downward motion of the actuator button 120. In one embodiment, the effective rearward motion of the actuator shaft 122 is at least twice the downward motion of the actuator button 120.
As shown in
Since there is no direct mechanical link between the handle 118 and the brake 116, with the only requirement being that the actuator shaft 122 of the handle 118 abut some point on the contact plate 124 of the brake 116, the handle 118 can be installed onto the rail 102 at any time during the assembly process of the shade 104. This allows the installation of the handle 118 when the rail 102 is still empty, which allows the use of fasteners extending from the inside of the rail 102 into the handle 118. In this particular embodiment, screws 138 are used. Since the screws 138 (See
Mounting the Handle on the Rail
As shown in
Angled, runnerless screw cavities in the handle 118 allow for easy and secure insertion of the screws 138 without requiring a complicated mold for casting the handle 118, as explained below.
Referring to
The guide surfaces 133 have a partial-cylindrical cross-sectional shape and are elongated in the front-to-back direction. As shown in
This arrangement of openings 132U, 132L with an intermediate slotted wall 136 may be accomplished with a simple mold that does not require special inserts and yet allows for the skewed threading of fasteners onto the handle 118.
Referring to
As the fastener 138 is threaded into the opening 132L, the ramped guide surface 133 pushes the end 140 of the fastener 138 into the slotted wall 136, so the screw grips tightly into the handle 118 in an otherwise unthreaded (runnerless) opening 132.
Assembly:
Referring to
The assembled brake 116 is then mounted into the rail 102 (See
It should be noted that, as the contact plate 124 is pushed rearwardly (transverse to the axis of rotation of the rod 112 and against the biasing force of the coil spring 158), the entire slide element 156 slides rearwardly, moving the ridge 196 on the rear wall 194 of the slide element 156 away from the splines 200 of the splined sleeve 160. This unlocks the splined sleeve 160 so it may rotate in either clockwise or counterclockwise directions (See also
While a specific handle 118 has been shown here, it is understood that various types of handles could be used to actuate the braking arrangements that are shown, including a handle that is molded into the rail, or even no handle at all, as long as there is some way to move the actuator shaft 122 (or some other type of pusher). The actuator shaft or pusher could be moved manually by a button or lever that is not associated with a handle or by an electrically-operated actuator or some other actuator mounted on the rail.
It will be obvious to those skilled in the art that modifications may be made to the embodiments described above without departing from the scope of the present invention as claimed.
This patent application is a continuation of and claims the benefit of priority to U.S. patent application Ser. No. 14/326,616, filed Jul. 9, 2014, which in turn claims the benefit of priority to U.S. Patent Application Ser. No. 61/847,117, filed Jul. 17, 2013 and U.S. Patent Application Ser. No. 61/873,035, filed Sep. 3, 2013. Each of the foregoing patent applications is hereby incorporated by reference herein in its entirety for all purposes.
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