The invention herein pertains to window hardware in general and in particular to a window opening control device similar to a window vent stop but used to control the manner in which window sashes may be moved relative to one another, particularly vertically.
While windows come in a variety of shapes, sizes and types, two of the most common types of windows in use are known as hung windows and sliding windows. Both of these types of windows have at least one sash that slides relative to another sash as the window is open or closed. With a double hung window, two sashes can move independent of one another in a vertical, up/down direction whereas with a double sliding window the sashes slide in a horizontal, side-to-side direction. The single hung and single slider window variations have only one moving sash while the other is fixed.
There is often a need to open the window to allow fresh air to enter the building or for stale air to exit. A partially or fully open window, however, presents an easy access point to enter the premises and thus presents a security risk. In addition, a fully open window presents a safety risk for a child or small adult who might fall out of the window if the opening is large enough. Moreover, it is often desired to open a window, particularly the single hung and double hung window, at least partially even when raining outside and allow in fresh air, or vent stale air, while minimizing the amount of water entering the premises. Vent stops have been developed and used in the prior art to achieve these objectives.
Generally speaking, a vent stop is a device that is installed in the outermost window sash on the surface against which the innermost sash slides. The vent stop is recessed into the sash so as to be flush with the surface of the sash when not in use. When needed, the stop is manually activated to raise a portion of the stop above the surface of the sash, thus limiting the ability of the two sashes to slide against one another.
Several prior art window stop devices have been proposed, including U.S. Pat. Nos. 5,575,116; 8,235,430; 8,360,484; and 8,806,809. The disclosures of these references are incorporated herein in their entirety by reference. While these prior art devices function well enough, they are complicated to manufacture and involve intricate detent mechanisms to maintain the stop blocks in the closed position which makes them undesirable and expensive.
Accordingly, there is a need for a window opening control device in the nature of a specialized window vent stop that has minimal moving parts and is simple to manufacture, assemble and operate.
In accordance with a preferred embodiment, a window opening control device comprises a housing having a peripheral flange defining an opening and a body depending from the peripheral flange. The housing is equipped with a clip at one end and a spring clamp at the other to provide for a snap lock type installation like that of a vent stop into a corresponding opening in the sash. A stop block is mounted within the body of the housing for rocking motion about a generally centrally located pivot point and is positioned within the opening in the flange. The stop block has a first wing and a second wing oriented at an obtuse angle relative to one another, forming a butterfly shaped member. The first wing of the stop block is oriented to engage a window sash when the sash is in a down position. By depressing the first wing into the housing, the second wing will rise toward the flange as the stop block pivots. Depressing the second wing into the housing causes the first wing to rise. The push to open, push to close operation causes a rocking movement of the stop block. Ridges on the first wing coordinate with a respective pair of spring legs on the interior of the housing to retain the first wing in a closed position wherein the first wing is retracted within the housing. In this position, the second wing may be depressed, against the force of the ridges and spring legs to raise the first wing into the up position.
For a better understanding of the invention and its operation, turning now to the drawings,
With reference to
Rear end 19 of housing 12 preferably includes a ledge 22 having a flat upper surface 23 that is spaced from the bottom of semi-circular flange 21. The distance between the ledge surface 23 and the flange 21 may be selected based on the typical thickness of the material used to build the sash, most often vinyl or fiberglass in current windows. The front end 18 of the housing 12 preferably includes a spring leg 24 connected at a proximal end to the bottom 25 of the housing 12 and extends outwardly therefrom at an angle oriented toward the semi-circular flange 20. The distal end 26 of the spring leg 24 extends beyond the leading edge 27 of semicircular flange 20.
The window opening control device 10 can easily be installed into a suitably sized and shaped opening in the widow sash. For example, the rear end 19 may be inserted first by positioning the edge of the opening in the sash within the space between the ledge surface 23 and the underside of flange 21 to frictionally engage the sash material between the ledge 22 and the flange 21. The front end 18 of the housing 12 may be pivoted toward the sash, forcing the spring leg 24 toward the front end 18 of housing 12. Once the spring leg 24 is no longer in contact with the edge of the opening in the sash, the spring leg 24 reverts back to its normal extended position shown in
The front and rear ends 18, 19 of the housing 12 are preferably integrally foil led with the right half 13 of housing 12 in the Figures, although this need not always be the case. It is preferred to make the housing members 13, 15 asymmetrical and not merely mirror images of one another for ease of manufacture and assembly, but it is noted to be within the skill of the ordinary artisan to make suitable modifications if desired.
With reference now made to
The stop block 14 has a cylindrical pivotal protrusion 34 located in the general center of the stop block 14. A corresponding protrusion (not shown in the Figures) is located on the opposite side of the stop block 14 and in alignment with cylindrical pivotal protrusion 34. These cylindrical pivotal protrusions 34 frictionally fit within corresponding recesses 29, (only one shown in
To further guide the rocking motion of stop block 14, a pair of cylindrical projections 36 is provided on the stop block 14. These cylindrical projections 36 are preferably sized and shaped to fit within corresponding curved channels 38 in the inner surfaces of the right side 13 and left side 14 of the housing 12. Only one projection 36 and one channel 38 are shown in
A ridge projection 40 is preferably located on the lower portion of front edge 31 of wing 30. A similar ridge projection 41 may be defined along the bottom surface 42 of the stop block 14 and about in the center, below the pivot point cylindrical protrusion 34. To move the stop block 14 from the open position to the closed position, the first wing 30 is depressed toward the housing 12. Upon such movement, ridge projection 40 may engage a ridge projection 43 on spring leg 44, located on the inner surface of left side 15 of housing 12. Similarly, ridge projection 41 may engage a ridge projection 45 on spring leg 46, also preferably located on the inner surface of left side 15 of housing 12. Upon such engagement, the spring legs 44, 46 will deform and/or deflect away from the ridge projections 40, 41 as shown by arrows 47 and 48 in
The illustrations and examples provided herein are for explanatory purposes and are not intended to limit the scope of the appended claims. Changes in the shapes and materials employed herein are anticipated by those skilled in the art as different plastics, sizes and configurations may be used as available without departing from the inventive concept divulged.
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