SASH LOCK CAPABLE OF BI-DIRECTIONAL ENGAGEMENT

Abstract

A sash lock for a sash window assembly is disclosed. The sash window assembly includes an upper sash window and a lower sash window. Each of the sash windows is mounted within opposed guide rails on a master frame. At least one of the sash windows is slidable within the frame relative to the other sash window. The sash lock comprises either a keeper, with a keeper opening, for mounting on a rail of one of the sash windows or a recess in the lower rail of the upper sash. The sash lock disclosed herein includes a housing having a hole, an actuator arm, and a cam having a cam element for receipt into the keeper opening or the recess. The locking assembly also includes a shaft extending through the housing hole and operably coupling the actuator arm to the cam.

Claims

1. A sash lock for a sash window assembly, the sash window assembly including an upper sash window and a lower sash window, each of the sash windows mounted within opposed guide rails on a master frame, wherein at least one of the sash windows is slidable within the frame relative to the other sash window, the sash lock comprising: a slot disposed within a lower rail of the upper sash; and a locking assembly for mounting on an upper rail of the lower sash, the locking assembly further comprising: a housing comprising a raised section with an internal surface and an external surface, a hole through the raised section and two lower sections oppositely disposed from one another across the raised section; an actuator arm with a shaft extending outwardly therefrom; a cam with a through hole therein, the cam disposed beneath the housing and shaped as a truncated circle with a linear edge segment, a base and an elevated portion disposed atop the base and opposite the linear edge segment, a top surface of the elevated portion is closely spaced to the interior surface of the housing; the actuator arm shaft extending through the housing hole as well as the cam through hole and operably coupling the actuator arm to the cam; and the actuator arm shaft and the cam through hole having corresponding circumferential surfaces; wherein rotation of the actuator arm shaft in either clockwise or counter-clockwise causes the cam to rotate the base portion into the slot in the lower frame member of the upper sash prevent movement of the upper and lower sashes.

2. The sash lock for a sash window assembly of claim 1, wherein a circular boss extends upwardly from the cam base and the boss surrounds the through hole.

3. The sash lock for a sash window assembly of claim 1, wherein the elevated portion spans in the range of about 45 to 90 degrees of the total circumference of the cam.

4. The sash lock for a sash window assembly of claim 1, wherein the elevated portion of the cam includes an outermost circumferential surface co-extensive with a portion of the outermost circumference of the base.

5. The sash lock for a sash window assembly of claim 4, wherein the elevated portion of the cam comprises a surface coextensive with the circular boss.

6. The sash lock for a sash window assembly of claim 1, wherein the elevated portion has first and second laterally opposed surfaces substantially perpendicular to the base.

7. The sash lock for a sash window assembly of claim 1, wherein the top surface of the elevated portion of the cam is spaced to no greater than 0.10 inch from the interior surface of the housing.

8. The sash lock for a sash window assembly of claim 1, wherein the linear edge segment is a chord C with a length dependent upon the central angle and the radius R of the cam.

9. A sash lock for a sash window assembly, the sash window assembly including an upper sash window and a lower sash window, each of the sash windows mounted within opposed guide rails on a master frame, wherein at least one of the sash windows is slidable within the frame relative to the other sash window, the sash lock comprising: a keeper for mounting atop a lower rail of the upper sash, the keeper including a keeper opening; and a locking assembly for mounting atop an upper rail of the lower sash window, the locking assembly including: a housing having a through hole; an actuator arm; a cam with a through hole and a base, the cam disposed beneath the housing for bi-directional rotational receipt into the keeper opening, the cam shaped as a truncated circle with a linear edge segment, and an elevated portion disposed atop the base and opposite the linear edge segment; and a shaft extending from the actuator arm, the shaft passing through the housing hole and the cam through hole, the shaft operably coupling the actuator arm to the cam, wherein the shaft and the hole are configured with corresponding circumferential surfaces.

10. The sash lock for a sash window assembly of claim 9, wherein the keeper is secured to the lower rail of the upper sash by at least two fasteners.

11. The sash lock for a sash window assembly of claim 9, wherein the height of the keeper opening is about 0.05 inches greater than the thickness of the base of the cam.

12. A sash lock for a sash window assembly, the sash window assembly including an upper sash window and a lower sash window, each of the sash windows mounted within opposed guide rails on a master frame, wherein at least one of the sash windows is slidable within the frame relative to the other sash window and the upper sash window includes a slot disposed within a bottom rail of the upper sash, the sash lock comprising: a locking assembly for mounting on an upper rail of the lower sash window, the locking assembly comprising: a housing having a hole therein; an actuator arm having a shaft disposed along a rotational axis and within the aperture of the housing; and a cam disposed beneath the housing and configured as a multi-level truncated circle and adapted for bi-directional rotational receipt into the slot; wherein rotation of the actuator arm in either direction away from perpendicular to the upper rail of the lower sash window causes the cam to be received into the slot thereby preventing movement of the upper and lower sash windows.

13. A sash lock comprising: a lock mechanism comprising a rotatable cam disposed beneath a housing; the cam further comprising a base, an outer circumferential surface, a linear edge segment, a portion elevated above the base disposed opposite the linear edge segment, the cam configured for bi-directional rotation into at least one of a slot within a lower frame member of an upper sash or an opening in a keeper, thereby preventing movement of the upper and lower sashes.

14. A sash lock, comprising: a housing member having a hole therein; a latch cam with a through hole, the cam configured as a truncated multi-level disk disposed beneath the housing member; an actuator member with an actuator shaft disposed substantially perpendicular to the actuator member, the actuator shaft configured for receipt into the housing member hole and the latch cam through hole, the latch cam opening and actuator shaft having corresponding circumferential surfaces; wherein, the actuator member is configured for bi-directional rotation to accomplish the insertion and removal of the latch cam into a structure to prevent movement of an upper and a lower window sash relative to one another, each of the sash windows mounted within opposed guide rails on a master frame, wherein at least one of the sash windows is slidable within the frame relative to the other sash window.

15. The sash lock of claim 14, wherein the structure is a recess in the lower rail of the upper sash.

16. The sash lock of claim 14, wherein the structure is a keeper with a keeper opening.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 illustrates a perspective view of a window master frame;

[0014] FIG. 2 illustrates a perspective view of upper and lower sash rails in proximity to one another with an embodiment of the sash lock in position;

[0015] FIG. 3 illustrates a partially exploded view of an embodiment of the sash lock;

[0016] FIG. 4 illustrates an exploded view of an embodiment of the sash lock;

[0017] FIG. 5 illustrates a perspective view of a window master frame and embodiment of the sash lock in position on the rail of the lower sash;

[0018] FIG. 6A illustrates a plan view of an embodiment of the sash lock with the actuator arm to the right in a locked position;

[0019] FIG. 6B illustrates a plan view of an embodiment of the sash lock with the actuator arm to the left in a locked position; and

[0020] FIG. 6C illustrates a plan view of an embodiment of the sash lock with the actuator arm perpendicular to the orientations in FIGS. 6A and 6B and in an unlocked position.

DETAILED DESCRIPTION

[0021] The following description is of various exemplary embodiments only, and is not intended to limit the scope, applicability or configuration of the present disclosure in any way. Rather, the following description is intended to provide a convenient illustration for implementing various embodiments including the best mode. As will become apparent, various changes may be made in the function and arrangement of the elements described in these embodiments without departing from the scope of the appended claims.

[0022] As seen in FIG. 1, disclosed herein is a sash lock 10 for use in a sash lock window assembly 12. The sash window assembly 12 includes an upper sash window 14 and a lower sash window 16. Each of the sash windows are mounted within opposed guide rails 20, 22 on a master frame 24, wherein at least one of the sash windows is slidable within the frame 24 relative to the other sash window.

[0023] As seen in FIGS. 2 and 3, the sash lock 10 operates in a first configuration by engaging within a slot 28 disposed within a lower rail 30 of the upper sash 14 and preventing movement of the upper sash 14 relative to the lower sash 16. The sash lock 10 includes a housing 34 with a raised section 36, downwardly extending flanges 35 and a building exterior-facing cam opening 37. The housing 34 includes an interior surface 38 and an exterior surface 40 as well as a hole 42 through the raised section 36. The housing 34 further includes two lower sections 44, 46 oppositely disposed from one another across the raised section 36 and threaded fasteners 50 passing through openings 52 in the two lower sections 44, 46 securing the housing 34 to the top surface 54 of the upper rail 56 of the lower sash 16.

[0024] As seen in FIG. 3, the sash lock 10 further utilizes a cam 64 with a through hole 66 therein. The cam 64 is positioned beneath the housing 34 and is shaped as a truncated circle with a linear edge segment 68 and an elevated portion 70 disposed opposite the linear edge segment 68. The cam 64 also includes a top surface 72 of the elevated portion 70. When in an operational position atop the upper rail 56 of the lower sash 16, the cam 64 is closely spaced to the interior surface 38 of the housing 34 such that a gap of no greater than 0.10 inches and preferably no greater than 0.05 inches exists between the top surface 72 of the elevated portion 70 and the interior surface 38 of the housing 34.

[0025] The cam 64 includes a base 74 with a top surface 76 and a bottom surface 78. Extending upwardly from the top surface 76 of the base 74 is a circular shaped boss 80. The boss 80 extends upwardly to the boss upper surface 82. The upper surface 72 of the elevated portion 70 of the cam 64 also achieves a height roughly equivalent to the height of the upper surface 82 of the boss 80. As previously discussed, the gap separating the boss upper surface 82, the elevated portion upper surface 84 and the interior surface 38 of the housing 34 is no greater than 0.10 inch and preferably no greater than 0.05 inches. At the center 86 of the boss 80 is the through hole 66, preferably with a non-circular cross-section, the rationale for such preferred non-circular cross-section is discussed below. Disposed directly and symmetrically opposite the linear edge segment 68 from the through hole 66, the elevated portion 70 of the cam 64 spans in the range of about 45 to 90 degrees of the total circumference.

[0026] As seen in FIG. 3, the elevated portion 70 of the cam 64 includes an outer edge 94 that is co-extensive with an outer edge 92 of the base 74. The elevated portion 70 of the cam 64 also includes an inner edge 96 that is co-extensive with an outer edge 98 of the circular boss 80. The elevated portion 70 also has first and second laterally opposed vertical surfaces 100, 102 substantially perpendicular to the base 74. As discussed above, the linear edge segment 68 is a chord C, the length of which is inter-dependent upon the central angle and the radius R of the cam 64.

[0027] As seen in FIG. 4, the sash lock 10 utilizes an actuator arm 108 with a shaft 110 extending outwardly from the actuator arm 108. The actuator arm shaft 110 extends through the housing hole 112 as well as the cam through hole 66 operably coupling the actuator arm 108 to the cam 64 because the actuator arm shaft 110 and the cam through hole 66 have corresponding circumferential surfaces 114, 116 that are preferably non-circular. The actuator arm shaft 110 preferably engages with the cam 64 with a non-circular configuration to eliminate slippage between the actuator arm shaft 110 and the through hole 66. Once the actuator arm shaft 110 is pressed into the cam through hole it is retained in that position and not readily removed during operation.

[0028] As seen in FIG. 5, an alternative utilization of the sash lock 10 is for receipt not into a slot 28 in the lower rail 30 of the upper sash 14 but into a keeper 120 that is fastened to an upper surface 122 of the lower rail 30 of the upper sash 14. The keeper 120 is generally a bracket feature that is mounted by standard fasteners 124 to the upper surface 122 and includes a keeper opening 126. The keeper opening 126 is an opening configured to receive the rotatable cam 64 and prevent motion of the upper and lower sash 14, 16 relative to one another.

[0029] In operation, the sash lock 10 is in an unlocked position when the actuator arm 108 extends perpendicular to the rails 30, 34. To engage the sash lock 10 so that it restricts movement of the upper and lower sashes 14, 16 relative to one another the actuator arm 108 is rotated, typically by hand, roughly a quarter turn either in a clockwise or counterclockwise direction. Rotation of the actuator arm 108 causes the actuator arm shaft 110 to similarly rotate due to the corresponding circumferential surfaces. As previously noted, a non-circular cross-sectional shaft is preferred so that slippage between the shaft 110 and the through hole 66 of the cam 64 does not result upon rotation of the shaft 110.

[0030] As seen in FIG. 6A when the actuator arm 108 rotates the cam 64 counter-clockwise (from the orientation seen in FIG. 6C) the linear edge segment 68 transitions from being aligned with the exterior facing edge 114 of the housing 34 to an orientation where only a portion of the base 74 extends outwardly from the exterior facing edge 114 of the housing 34 into the slot 28 (not shown) or alternatively the keeper opening 126 (not shown). As the actuator arm 108 rotates the cam 64 rotates counter-clockwise the elevated portion 70 (shown in phantom lines) remains beneath the housing 34 and because of the close-proximity of the top surface 72 of the elevated portion 70 to the interior surface 38 of the housing 34 the entire cam 64 is restrained against upward movement. As an upward force is applied to the lower sash 16 or a downward force is applied to the upper sash 14 the cam 64 orientation remains essentially horizontal due to the restraint provided by the housing 34.

[0031] As seen in FIG. 6B, as the actuator arm 108 rotates the cam 64 clockwise (from the orientation seen in FIG. 6C), the linear edge segment 68 transitions from being aligned with the exterior facing edge 114 of the housing 34 to an orientation where only a portion of the base 74 extends outwardly from the exterior facing edge 114 of the housing 34 into the slot 28 (not shown) or alternatively the keeper opening 126 (not shown). As the cam 64 rotates horizontally counter-clockwise the elevated portion 70 remains beneath the housing 34 and because of the close-proximity of the top surface 72 of the elevated portion 70 to the interior surface 38 of the housing 34 the entire cam 64 is restrained against upward movement. As an upward force is applied to the lower sash 16, or a downward force is applied to the upper sash 14, the cam orientation remains essentially horizontal due to the restraint provided by the housing 34. The sash lock is equally effective at restricting movement of the upper and lower sashes relative to one another without limitation on whether the actuator arm 108 rotates clockwise or counterclockwise.

[0032] FIG. 6C reveals the sash lock in a position with the cam 64 fully retracted beneath the housing 34. To achieve this orientation the actuator arm 108 is rotated perpendicular to the window rails 30, 34. With the cam 64 fully retracted, and therefore not inserted into a recess in a rail or into a keeper opening 126.

[0033] Having shown and described various embodiments of the present invention, further adaptations of the methods and systems described herein may be accomplished by appropriate modifications by one of ordinary skill in the art without departing from the scope of the present invention. Several of such potential modifications have been mentioned, and others will be apparent to those skilled in the art. For instance, the examples, embodiments, geometries, materials, dimensions, ratios, steps, and the like discussed above are illustrative and are not required. Accordingly, the scope of the present invention should be considered in terms of the following claims and is understood not to be limited to the details of structure and operation shown and described in the specification and drawings. Moreover, the order of the components detailed in the system may be modified without limiting the scope of the disclosure.