The present invention relates generally to the field of window locks, and more particularly to an improved self locking window latch for a sliding window. A window latch secures a window sash when it is in the closed. In sliding windows, where a window sash is slid relative to another sash, the latch is first released in order to slide the window to the open position. When the window is slid back to its closed position, the latch is used to lock the window in place. If the latch is not moved to the locked position, the window may be opened by simply sliding the window to the open position permitting unwanted entry. An automatically locking mechanism helps to ensure that the window sash is properly locked when the window is slid to the closed position. One such locking mechanism is disclosed in U.S. Pat. No. 5,901,501. The latch described in the '501 patent includes a handle that is in an upwardly pointing direction, the locking mechanism is released by depressing the handle downwardly, the window sash is then slid in a direction opposite to the first direction that the handle is depressed. Once the window sash is slid open the handle disclosed in the '501 patent the handle returns to the upward position.
It would be desirable to provide an automatically locking mechanism where the handle is moved in the same direction that window sash slides when moving the window sash to the open position. Further it would be desirable for the handle to have a first position when the window sash is locked and a second perceptually visible different position when the window sash is not locked. It would also be desirable for the engagement elements to be retained in an unlocked position while the window sash is open and automatically move to the locked position when the window sash is closed. Further it would be desirable to achieve the noted features while providing a secure lock.
One embodiment of the invention relates to a window latch for a sliding window having a sliding sash including a latch plate and a housing. The housing includes an engagement element movable relative to the housing from a locked position operatively engaged with the latch plate to an unlocked position disengaged from the latch plate. A handle is operatively coupled to the engagement element and movable from a first position to a second position in a first direction corresponding to the direction the sliding sash to which the handle is attached moves to an open position. The handle operatively moves the engagement element from the locked position to the unlocked position as the handle is moved in the first direction toward the second position.
In another embodiment a window latch for a sliding sash window includes a handle movable between a first position and a second position. An engagement member is movable between an extended locked position and a retracted unlocked position. The engagement element is biased toward the extended locked position by a spring element. A stop member is movable from an engaged position in which the stop member retains the engagement element in the retracted unlocked position to a disengaged position in which the engagement element is free to move to the extended locked position. A latch plate is configured to receive the engagement element in the extended locked position and a strike member configured to contact a portion of the stop member. The stop member being moved to the disengaged position when the stop member contacts the strike member, and being biased to the engaged position when the stop member does not contact the strike member.
In still another embodiment a window latch for a sliding window includes a first sash movable between a closed position and an open position along a first direction, a handle movable in the first direction from a first lowered position to a second raised position. An engagement element is releasably movable from an extended locked position to a retracted unlocked position. The handle is operatively held in the second raised position by a spring element when the first sash is in the open position and the engagement element is in the retracted unlocked position.
In yet another embodiment a sliding window includes a first sash slidable relative to a second sash. A latch is operatively attached to the first sash and a latch plate is operatively attached to the second sash. The latch includes a engagement element that extends from the first sash and is received in an opening in the second sash to lock the first and second sash together. A handle pivots from a first lowered position proximate the first sash to a second raised direction where a free end of the handle is away from the first sash in the same direction that the first sash moves when the first sash is opened relative to the second sash. The handle retracts the engagement element from the second sash unlocking the first and second sash as the handle is moved toward the second position.
Additionally, the handle may be held in at least a partially raised position relative to the first sash when then the first sash is open and the engagement element is in the retracted unlocked position. The handle being automatically returned to the first lowered position when the first sash is closed and the engagement elements are biased to the locked position. Further, the engagement element may automatically be returned to the extended locked position when the first sash is moved to the closed position.
In still a further embodiment, a method of unlocking and locking a sliding window having a first and second sash includes securing a latch to the first sash and a latch plate to the second sash. The latch includes a handle, and an engagement element. Unlocking the engagement element from the latch plate by moving the handle in the same direction that the first sash moves to the open position relative to the second sash. Retaining the handle in a raised position by a spring element while the first sash is in the open position and the engagement element is in the unlocked position. Moving the first sash toward the closed position and automatically releasing and biasing the engagement element into the locked position and automatically moving the handle to the lowered position when the engagement element is in the locked position.
Referring to
The latch mechanism 10 may be used on a sliding window including horizontal sliding windows and vertical sliding windows. A horizontal sliding window is often referred to as a horizontal slider while a vertical sliding window is often referred to as a single hung or double hung window. While the latch mechanism 10 may be used with different types of sliding windows including those identified above, latch mechanism 10 will be described relative to a vertical sliding window. Accordingly, the direction “up” or “upper” is used to reference a general vector direction away from the force of gravity or the direction first sash 18 moves as it is opened relative to second sash 22. The term “rear” is used to describe the surface of the first sash that is proximate to or closer to the second sash. While the term “front” is used to describe the surface that a person would see facing the window from inside of a building structure. The term “rail” as used in the description describes the horizontal rail on the sash. However, when latch mechanism 10 is used on a horizontal sliding window the term stile would be more appropriate. In the case of a horizontal sliding window, the term “up” would be the direction the first sash moves as the first sash is being opened relative to the second sash.
Latch mechanism 10 provides an easy and intuitive operation to open a window sash 18. A user simply raises handle 24 in an upward direction thereby unlocking the bolt assemblies 36 from the latch plate 14 and moves the first sash 18 in an upward direction. As described below in the preferred embodiment handle 24 is pivotally coupled to the window sash, however, the general direction that the handle moves is in an upward direction. Accordingly, as used herein the movement of the handle is referred to as moving in a first direction that corresponds to the vector direction of the movable sash in the window. As first sash 18 is opened relative to second sash 22, the lockout assembly 34 keeps bolt assemblies 36 in a partially retracted unlocked position. The partial retraction of bolt assemblies 36 prevents possible damage to the window frame, glass or applied mounting bars. Handle 24 remains in a partially raised position without the assistance of the user when first sash 18 is not in the fully closed position and latch mechanism 10 is not positively locked. When the user returns first sash 18 to a closed position, lockout assembly 34 is tripped and allows bolt assemblies 36 to automatically extend into the apertures 160 of latch plate 14 thereby positively locking first sash 18 and second sash 22 together. Handle 24 automatically returns to a flush downward position providing a visual indicator that latch mechanism 10 is positively locked.
Referring to
Handle 24 includes a top plate 68 having a top surface 70, a bottom surface 72, a rear edge 74 and a front edge 76. Pivot pins 66 extend from respective sides 78, 80 of top plate 68 proximate rear edge 74. A pair of arms 82 extend downwardly from the bottom surface 72 of top plate 68 to retract the sliding bolt assemblies 36. Referring to
Referring to
Base 32 includes a bottom panel 94 a front wall 96, a rear wall 98 and a pair of side walls 100. Extending upward from bottom panel 94 and substantially parallel to the side walls 100 are channel side walls 102. A bolt slide channel 103 is formed between each pair of side walls 100 and 102. Each side wall 100 includes a notch 104 located on an upper edge thereof. Extending from a rear side of front wall 96 in each of bolt slide channel 103 is a post 106 configured to received a bolt spring 166.
Another post 108 configured to receive a pawl spring 124 extends upwardly from the bottom panel 94 intermediate the channel side walls 102. Rear wall 98 includes an aperture 110 and front wall 96 includes an aligned aperture 112. A fastener 114 extends through aperture 110 in cover plate 30, aperture 115 in bezel frame 26, aperture 110 in base rear wall 98, aperture 112 in base front wall 96 and into a nut 116. Nut 116 is secured to a downwardly extending portion 45 of bezel frame 26. Nut 116 extends from bezel frame 26 through an opening in rail 16. In a preferred embodiment, nut 116 is operatively connected to bezel frame 26 with a tongue and groove arrangement. In this manner the components are secured to one another.
Referring to
Referring to
Referring to
Latch mechanism 10 is installed on the first and second sashes. Handle 24 is located within bezel frame 26 by bringing the leading or front edge 76 through opening 172 of bezel frame 26. Handle pivots 66 are seated within pivot bearing or groove 62 in bezel frame 26. Latch 12 is assembled by first connecting lockout assembly 34 by connecting pivots 118 on a supporting groove or bearing portion on base 32. A lock spring 124 is located on post 108 and extends upwardly toward pawl 120. Bolt housings 128 are placed within a respective bolt housing channel 103. A bolt spring 166 is located over each post 106 and fit between front wall 96 and a center wall 140 of bolt housing 128. A handle spring 150 is located within bolt housing 128 between rear wall 141 and a movable shuttle 144. Cover plate 30 is secured to base 32 with a plurality of fasteners 84. Of course a single fastener or other known fasteners may be used to secure the cover to the base. The cover 30 and base 32 are located within an opening region in rail 16 by fitting three locator pins 90 within three respective recesses in rail 16.
Bezel frame 26 and handle 24 are snapped onto a routed opening in first rail 16 of first sash 18. A downwardly extending flange or tab 95 is located within opening 93 in cover 30. A fastener or bolt 114 is thread through aperture 88 in flange 86 of cover 30, through opening 115 in tab 95 of bezel frame 26, opening 110 in rear wall 98 of base 32, through opening 112 in front wall 96 of base 32 and finally into a nut 116 that is operatively connected to an inside surface 119 of downwardly extending portion 45 of bezel frame 26. In this manner access to the latch mechanism is only through the rear surface of the movable sash 18 that faces second sash 22. Latch plate 14 is secured to second sash 22 with a fastener 174.
Referring to
Referring to
To unlock the latch a front edge or 76 of handle 24 is raised away from first rail 16. Referring to
Referring to
Referring to
When a user closes the window by sliding first sash 18 back to the closed position, the top leading edge of pawl 120 contacts strike portion 164 of latch plate 14. As a result, lockout assembly 34 rotates about pivots 118 releasing ramp 122 from the back edge of lock tab 154. Once lock tab 154 is no longer constrained by ramp 122 of lockout assembly 34, bolt housing 128 is biased rearward by bolt spring 166. Bolt housing 128 is biased rearward such that the rear portion 134 of bolt housing 128 is located within apertures 160 of latch plate 14. As bolt housing 128 is moved rearward, handle 24 is biased to the closed flush position by center wall 140 thereby indicating that the latch is in a locked configuration. If the bolt housing does not properly align with apertures 160 of latch plate 14, a rear portion 134 of each bolt housing 128 includes a beveled portion 136 that will contact latch plate 14 as first sash 18 is being moved to a closed position relative to second sash 22. As beveled portion 136 contacts latch plate 14, bolt housing 128 is slid toward the front of the base 32 until rear portion 134 of bolt housing 128 clears front surface 162 and enters into aperture 160 of latch plate 14. In the preferred embodiment, lockout assembly 34 does not release bolt housings 128 until rear portion 134 of bolt housings 128 are aligned with apertures 160.
Each bolt housing 128 slides independently of the other bolt housing 128. While a single lockout assembly 34 locks both bolt housings 128 in the open and unlocked position, once the lockout assembly 34 disengages with the bolt housing lock tabs 154, each bolt housing 128 moves independently. This independent motion limits potential jams of the bolts within the housing. Even if one bolt housing 128 becomes jammed or stuck, the other bolt housing 128 can slide to the fully locked position thereby locking the first sash 18 relative to the second sash 22. Further the linear motion of the bolt housing 128 helps to reduce possible jamming of bolt housings 128 within the latch mechanism.
Referring to
Referring to
Bezel frame 226 includes a top surface 246 and an opposing bottom surface 248 that contacts the top surface 238 and ledge 244 of first rail 216. Bezel frame 226 also includes a downwardly extending portion 245 that contacts and covers a portion of downwardly extending portion 242 of first rail 216, a top land region 250 generally perpendicular to downwardly extending portion 245, and a rear portion 264 generally opposite of downwardly extending portion 245. Downwardly extending portion 245 has coupling features, shown as two generally L-shaped brackets or flanges 247 that are configured to receive a fastener bar 316. Rear portion 264 includes a downwardly extending tab or protrusion 252 that may form an inward extending catch 256 that is configured to clip under an opposing bottom surface 258 of top surface 238 of first rail 216. Tab 252 helps positively secure bezel frame 226 to first rail 216. Bezel frame 226 further includes two tabs or flanges 295 that extend downward from bottom surface 248 that are configured to receive fasteners 314 in apertures 315. Bezel frame 226 further includes two apertures, recesses or bearings 262 proximate a rear portion 264 of bezel frame 226 to receive two pivot pins 266 of handle 224.
Handle 224 includes a top plate 268 having a top surface 270, a bottom surface 272, a rear edge 274 and a front edge 276. Pivot pins 266 extend from respective sides 278, 280 of top plate 268 proximate rear edge 274. An arm 282 extends downwardly from the bottom surface 272 of top plate 268 to retract sliding bolt assembly 236. Referring to
Referring to
Base 232 includes a bottom panel 294 a front wall 296, a rear wall 298 and a pair of side walls 300. Extending upward from bottom panel 294 and substantially parallel to the side walls 300 are channel side walls 302. A bolt slide channel or bolt housing channel 303 is formed between side walls 302. Rear wall 298 forms an opening 326 that is configured to allow lockout assembly 234 to protrude outside base 232. Rear side of front wall 296 includes two depressions or recessed areas 306 in bolt slide channel 303 that are configured to received bolt springs 366. A post 308 configured to receive a pawl spring 324 extends upwardly from bottom panel 294 between one of side walls 300 and one of side walls 302.
Base further includes a plurality of posts 284 (e.g., pegs, protrusions, outcroppings, etc.) that extend upward from base 232. Posts 284 are configured to be received by corresponding apertures 285 in cover plate 230 and substantially align cover plate 230 with base 232. Rear wall 298 includes an aperture 310 and front wall 196 includes an aligned aperture 312. A fastener 314 extends through aperture 310 in base rear wall 298, aperture 315 in bezel frame 226, aperture 312 in base front wall 296 and into apertures 317 in fastener bar 316. Fastener bar 316 is received by brackets 247 in downwardly extending portion 245 of bezel frame 226. In a preferred embodiment, fastener bar 316 is operatively connected to base 232 with a tongue and groove arrangement and fasteners are coupled to apertures 317 (e.g., with a threaded connection). In this manner the components are secured to one another.
Referring to
Referring to
A channel 342 is formed in bolt housing 328 with a rear wall 341 and is configured to receive arm 282 of handle 268, shuttle 344, and handle spring 350. Channel 342 includes at least one inwardly projecting tongue 348. Shuttle 344 has at least one groove 346 and slides on tongue 348 in channel 342. Handle spring 350 extends between rear portion 334 and shuttle 344 to bias shuttle 344 into channel 342.
Latch mechanism 210 is installed on the first and second sashes 218, 222. Handle 224 is located within bezel frame 226 by bringing the leading or front edge 276 through opening 372 of bezel frame 226. Handle pivots 266 are seated within pivot bearing or groove 262 in bezel frame 226. Latch 212 is assembled by first connecting lockout assembly 234 by connecting pivots 318 on a supporting groove or bearing portion on base 232. A lock spring 324 is located on post 308 and extends upwardly toward pawl 320. Bolt housing 328 is placed within bolt housing channel 303. Bolt springs 366 are located in each depression 306 and fit between front wall 296 and posts 339 on bolt housing 328. A handle spring 350 is located within bolt housing 328 between rear wall 341 and a movable shuttle 344. Cover plate 230 is secured to base 232 by fitting posts 284 into apertures 285. Of course the cover plate may be coupled to the base by other suitable means (e.g., screws or other fasteners, glue, snap-fit connections, etc.). Bezel frame 226 and handle 224 are snapped onto a routed opening in first rail 216 of first sash 218. Fasteners or bolts 314 are thread through apertures 310, 315, and 312 and into apertures 317 of fastener bar 316 that is operatively connected to downwardly extending portion 245 of bezel frame 226. In this manner access to the latch mechanism is only through the rear surface of the movable sash 218 that faces second sash 222. Striker plate 214 is secured to second sash 222 with fastening features 374.
Referring to
Referring to
To unlock the latch a front edge 276 of handle 224 is raised away from first rail 216. Referring to
Referring to
Referring to
As shown in
When a user closes the window by sliding first sash 218 back to the closed position, the top leading edge of pawl 320 contacts strike portion 364 of latch plate 214. As a result, lockout assembly 234 rotates about pivots 318 releasing ramp 322 from the back edge of lock tab 354. Once lock tab 354 is no longer constrained by ramp 322 of lockout assembly 234, bolt housing 328 is biased rearward by bolt spring 366. Bolt housing 328 is biased rearward such that the rear portion 334 of bolt housing 328 is located within recessed area 360 of latch plate 214. As bolt housing 328 is moved rearward, handle 224 is biased to the closed flush position by bolt housing 328, thereby indicating that latch 210 is in a locked configuration. If bolt housing 328 does not properly align with recessed area 360 of latch plate 214, a rear portion 334 of each bolt housing 328 includes a beveled portion 336 will contact latch plate 214 as first sash 218 is being moved to a closed position relative to second sash 222. As beveled portion 336 contacts latch plate 214, bolt housing 328 is slid toward the front of the base 232 until rear portion 334 of bolt housing 328 clears front surface 362 and enters into recessed area 360 of latch plate 214. In the preferred embodiment, lockout assembly 234 does not release bolt housings 328 until rear portion 334 of bolt housing 328 is aligned with recessed area 360.
It is important to note that the construction and arrangement of the latch mechanism as described herein is illustrative only. Although only a few embodiments of the present inventions have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in the claims. For example, elements shown as integrally formed may be constructed of multiple parts or elements and vice versa, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of the present invention as defined in the appended claims. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions as expressed in the appended claims.
This application is a continuation of U.S. Pat. No. 14,533,527, filed Nov. 5, 2014, which is a continuation of U.S. patent application Ser. No. 13/457,788, filed Apr. 27, 2012, now U.S. Pat. No. 8,899,632, issued Dec. 2, 2014, which is a divisional of U.S. patent application Ser. No. 11/521,086 filed Sep. 14, 2006, now U.S. Pat. No. 8,182,001, issued May 22, 2012, all entitled “DIRECT ACTION WINDOW LOCK”, which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | 11521086 | Sep 2006 | US |
Child | 13457788 | US |
Number | Date | Country | |
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Parent | 14533527 | Nov 2014 | US |
Child | 16173106 | US | |
Parent | 13457788 | Apr 2012 | US |
Child | 14533527 | US |