Embodiments of the present application generally relate to latch mechanisms. More particularly, but not exclusively, embodiments of the present application relate to tubular latch mechanisms with accelerated bolt motion for multiple backset settings.
Certain locksets typically include a lock chassis assembly that is engaged with a latch assembly. Often, at least a portion of the lock chassis is installed in a cylindrical hole or opening in a door. The distance between the centerline of the opening relative to a side edge of the door is often referred to as the backset. The latch assembly that mates with the lock chassis often extends through a latch hole that extends from the side edge of the door to the cylindrical hole or opening. However, the distance that the latch assembly is to extend along at least the latch hole so as to operably engage the lock chassis may vary. More specifically, the backset setting may vary for different doors and/or applications. For example, traditionally, entryway devices can have backset settings of either 2⅜ inches or 2¾ inches. Thus, proper installation of the latch assembly often requires that the latch assembly be configured to accommodate the particular backset for that door. If this criterion is not met, the lockset may fail to function properly.
Additionally, lever or doorknobs often need to be turned approximately one-quarter of a revolution, such as, for example, rotated about 80 degrees to about 90 degrees, to displace the latch bolt of the latch bolt assembly from an extended, locked position to a retracted, unlocked position. Typically, when displaced to the retracted position, the latch bolt is withdrawn from extending into an strike opening in a frame or wall so that the latch bolt is at a position that does not prevent the associated entryway device (e.g., a door or gate) from being displaced from a closed position about an entryway to an open position. Further, the ability to accommodate bi-directional rotational displacement of the lever or doorknob to retract the latch bolt, as well as providing a latch assembly that is adjustable for different backsets, can increase the degree to which the lever or doorknob is to be rotated before the latch bolt reaches the retracted position.
Certain embodiments of the present application relate to a latch assembly that is adjustable between first and second backset settings. According to some embodiments, the latch assembly can include at least one cam that is rotatable about a cam axis, and a latch link that is linearly displaceable in a first direction by engagement with the at least one cam as the at least one cam is rotated in a first rotational direction. The latch assembly also includes a multiplier link that is rotatable about a multiplier link axis that is offset from the cam axis. The multiplier link can be rotatable in the first rotational direction by engagement with the latch link as the latch link is linearly displaced in the first direction. The latch assembly also includes a latch bar that is coupled to the multiplier link, the latch bar being linearly displaced in a second direction by rotation of the multiplier link in the first direction, the second direction being opposite of the first direction. The latch assembly also includes a latch bolt that is coupled to the latch bar, the latch bolt being displaced toward a retracted position by the displacement of the latch bar in the second direction. The latch assembly can also include a dead latch assembly having a dead latch link that is displaceable between a dead-latching position and a release position, the dead latch link blocking retraction of the latch bolt when the dead latch link is in the dead-latching position.
The description herein makes reference to the accompanying figures wherein like reference numerals refer to like parts throughout the several views.
The foregoing summary, as well as the following detailed description of certain embodiments of the present invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, certain embodiments are shown in the drawings. It should be understood, however, that the present invention is not limited to the arrangements and instrumentalities shown in the attached drawings.
Certain terminology is used in the foregoing description for convenience and is not intended to be limiting. Words such as “upper,” “lower,” “top,” “bottom,” “first,” and “second” designate directions in the drawings to which reference is made. This terminology includes the words specifically noted above, derivatives thereof, and words of similar import. Additionally, the words “a” and “one” are defined as including one or more of the referenced item unless specifically noted. The phrase “at least one of” followed by a list of two or more items, such as “A, B or C,” means any individual one of A, B or C, as well as any combination thereof.
The interior region 112 is configured to receive the insertion of at least a portion of the inner housing 109 through the first and/or second openings 114, 116 of the outer housing 108. Further, the interior region 112 of the outer housing 108 is configured to accommodate at least the partial rotational and axial displacement of the inner housing 109 within the interior region 112 of the outer housing 108. The outer wall 110 can further include an adjustment slot 118 that is adapted to receive the slideable displacement of an engagement member or detent 120 of the inner housing 109 as the latch assembly 100 is selectively adjusted between a first backset setting and a second backset setting. The adjustment slot 118 may have a variety of shapes and configurations. According to the illustrated embodiment, the adjustment slot 118 may include opposing first and second transversal slots 122a, 122b and an interconnected axial slot 124 that may, or may not, interconnect the first and second transversal slots 122a, 122b. Further, according to certain embodiments, the axial slot 124 may extend in a direction that is generally parallel to a longitudinal axis 126 of the outer housing 108, as shown, for example, in
The inner housing 109 includes an outer wall 132 that generally defines an inner region 134 of the inner housing 109. According to the illustrated embodiment, the inner housing 109 is generally cylindrical and extends between first and second openings 136, 138 that are located at opposing ends of the outer wall 132. The outer wall 132 of the inner housing 109 can also include one or more wall slots 140 that can accommodate displacement of other components of the latch assembly 100, including, for example, pivotal movement of a dead latch link 142, as discussed below. According to certain embodiments, the wall slots 140 can extend through the outer wall 132 so as to provide a passage between the inner region 134 of the inner housing 109 and a region outside of the inner housing 109. Additionally, according to certain embodiments, similar wall slots can extend through the outer wall 110 of the outer housing 108.
The outer wall 132 of the inner housing 109 can have a variety of different shapes and sizes. For example, in the illustrated embodiment, the outer wall 132 of the inner housing 109 has a generally cylindrical configuration. According to certain embodiments, the outer wall 132 of the inner housing 109 can include an engagement member 121 that can be displaced, deformed, deflected, and/or pivoted from a first position to a second position. In the illustrated embodiment, a pivot end 144 of the engagement member 121 is attached to an adjacent portion of the outer wall 132, while the remainder of the engagement member 121 is detached from adjacent portions of the outer wall 132. For example, in the illustrated embodiment, the engagement member 121 has a generally square or rectangular configuration that comprises a first pair of opposing sidewalls 146a, 146b and a second pair of opposing end walls 148a, 148b; one of the end walls 148b provides the pivot end 144, and the other end wall 148a and the sidewalls 148a, 148b are detached from adjacent portions of the outer wall 132. However, the engagement member 121 may have a variety of other shapes and configurations. Additionally, while in the illustrated embodiment the pivot end 144 is illustrated as a single, continuous portion or extension of the engagement member 121, according to other embodiments, the pivot end 144 can comprise one or more arms that provide pivot, deformation, deflection, or displacement points or portions of the engagement member 121 and/or of the outer wall 132. Additionally, the outer wall 132 can be constructed from a material, and/or have a wall thickness, that, when the engagement member 121 is subjected to a displacement force in a general direction toward the inner region 134, can accommodate the displacement or deformation of the engagement member 121 from the first position to the second position, as well as the general return of the engagement member 121 from the second position to, or around, the first position upon removal of the displacement force.
The engagement member 121 further includes the engagement projection 120, which generally extends outwardly from the engagement member 121. As discussed below in more detail, the engagement projection 120 is adapted to be received in the adjustment slot 118 of the outer housing 108. The engagement projection 120 may be positioned at a variety of locations along the engagement member 121. For example, as illustrated in at least
When the housing assembly 102 is being assembled, the inner housing 109 can be positioned in the interior region 112 of the outer housing 108, and the engagement member 121 can be inwardly displaced, bent, or deformed from the first position to the second position. When at such a position, the engagement projection 120 can be positioned to not prevent at least a portion of the inner housing 109, including the engagement projection 120, from being inserted into the interior region 112 of the outer housing 108 to a location in which the engagement projection 120 can be received into the adjustment slot 118. Thus, upon reaching the adjustment slot 118, the displacement force exerted on the engagement member 121 may be removed so that the engagement member 121 can be displaced from the second position and to, or towards, the first position.
Accordingly, when the engagement projection 120 is positioned within the adjustment slot 118, the inner housing 109 can be linearly or rotatably displaced. Moreover, the relative angular and linear positions of the outer and inner housings 108, 109 can be adjusted such that the location of engagement projection 120 within the adjustment slot 118 can be adjusted, such as, for example, to accommodate the outer and inner housings 108, 109 being at relative positions that accommodate the first or second backset settings of the latch assembly 100. For example, according to the illustrated embodiment, the engagement member 121 of the inner housing 109 can be at, or around, the first end 128 of the first transversal slot 122a when the latch assembly 100 is at the first backset setting, such as, for example, a backset setting of 2⅜ inches. Similarly, the latch assembly 100 can be at the second backset setting, such as, for example, a backset setting of 2¾ inches, when the engagement projection 120 is at or around the second end 130 of the second transversal slot 122b. Further, while the degree to which the relative angular position of the outer and inner housings 108, 109 can vary depending on embodiments, according to certain embodiments, displacement of the engagement projection 120 from the first end 128 of the first transversal slot 122a and/or the second end 130 of the second transversal slot 122b to the axial slot 124, and vice versa, can be about +/−40 degrees, depending on the direction of displacement.
Referencing
According to certain embodiments, one of the first retention member 150 and the second retention member 152 can be a retention projection 154 that extends toward the other of the first and second retention members 150, 152. Further, according to such an embodiment, the other of the first and second retention members 150, 152, can be two or more apertures 156a, 156b in the outer wall 110, 132 of the associated outer or inner housing 109, 110 that are sized to selectively receive insertion of at least a portion of the retention projection 154. For example,
If the latch assembly 100 is to be adjusted to the second backset setting, a force applied to the latch assembly 100 can be provided that at least overcomes the interference or obstruction provided by the engagement between the retention projection 154 and the first aperture 156a. If such a force is provided, the retention projection 154 may slide out of, or otherwise be displaced from, the first aperture 156a, and engage an adjacent portion of the outer wall 132 of the inner housing 109, thereby causing the outward pivotable displacement, deformation, and/or deflection of the retention tab 158. In such a situation, when the outer and inner housings 108, 109 are placed at relative positions associated with the latch assembly 100 being at the second backset setting, the retention tab 158 may be inwardly displaced, deformed, and/or deflected as at least a portion of the retention projection 154 is received in the second aperture 156b. While the above example is discussed in connection with the latch assembly 100 being adjusted from the first backset setting to the second backset setting, a similar process can occur when the latch assembly 100 is adjusted from the second backset setting to the first backset setting.
According to certain embodiments, the inner housing 109 can be secured to a back plate 160 and/or face plate 162. The face plate 162 and the back plate 160 can each include openings 164a, 164b that are sized to accommodate the axial displacement of at least a portion of a latch bolt 166 of the bolt assembly 106 around a first end 210a of the latch assembly 100. Further, according to the illustrated embodiment, the opening 164b of the face plate 162 can be configured to prevent rotational displacement of the latch bolt 166 about the opening 164b of the face plate 162. Moreover, to the extent that the latch bolt 166 and/or the face plate 162 is/are rotatably displaced (i.e., when adjusting the backset setting of the latch assembly 100), the latch bolt 166 can engage, or be engaged by, at least a portion of an edge or wall of the opening 164b of the face plate 162 so that the latch bolt 166 and the face plate 162 are generally rotatably displaced together. Further, the back plate 160 can be operably secured to the face plate 162 (i.e., by a mechanical fastener such as a rivet, bolt, or screw, among other connectors) such that the back plate 160 may be rotatably displaced with the face plate 162.
The opening 164a of the back plate 160 can be sized to receive the slideable displacement of at least a portion of the latch bolt 166. Additionally, according to certain embodiments, the opening 164a of the back plate 160 can be sized to receive the insertion of at least a portion of the inner housing 109 and, according to certain embodiments, received a portion of the outer housing 108. The back plate 160 and the face plate 162 can also include one or more apertures that are sized to receive a fastener, such as, for example, a screw. When the latch assembly 100 is secured to an entryway device, such as, for example, a door, the back plate 160 can abut a side edge of the entryway device and/or be positioned within a recess in the side edge of the entryway device, among other locations.
According to the illustrated embodiment, the bolt assembly 106 includes a latch bolt 166, a latch bar 168, a multiplier link 170, a latch link 172, one or more bolt biasing elements 174, and one or more cams 176. The bolt assembly 106 is adapted to be axially displaced between an extended, locked position, and a retracted, unlocked position. As previously discussed, when in the extended, locked position, and with the entryway device in a closed position, the bolt assembly 106 can be axially positioned so that the latch bolt 166 at least partially extends into an adjacent wall, door frame, and/or strike plate, among other structures, so as to at least attempt to prevent the entryway device from being displaced to an open position. When in the retracted, unlocked position, the bolt assembly 106 may be axially positioned, such as, for example, being at least partially withdrawn in or toward the entryway device so that the latch bolt 166 does not prevent the entryway device from being displaced from the closed position to an open position.
The latch bar 168 may be operably secured to the latch bolt 166 in a number of different manners. For example, as shown in
Referencing
According to the illustrated embodiment, when the latch assembly 100 is at the second backset setting, as shown in at least
With the latch bolt 166 extending through the face plate 162 and/or the back plate 160, rotational displacement of the face plate 162 and/or back plate 160 in the first rotation direction can facilitate similar rotation of the latch bolt 166, and, moreover, can result a change in the relative angular positions of the latch bolt 166 and the latch bar 168. Further, such an adjustment in relative angular positions of at least the latch bolt 166 and the latch bar 168 can result in the bolt fastener 184 being displaced from the second retention recess 204 and to a position in the adjustment recess 198 that is adjacent to the second retention recess 204, as shown, for example, in
In certain embodiments, with the bolt fastener 184 in the adjustment recess 198 near the second retention recess 204, the bolt biasing element can exert a force against the latch bolt 166 that seeks to bias the latch bolt 166 in an axial direction toward the first retention recess 202 while the second body 190 of the latch bar 168 can be coupled to a cover housing 208 at a second end 210b of the latch assembly 100. According to such an embodiment, the relative axial positions of at least the face plate 162 and/or the back plate 160 and the cover housing 208 and/or the outer housing 108 may be adjusted such that the axial distance between the first and second ends 210a, 210b of the latch assembly 100 is reduced. Such an adjustment of axial positions can facilitate an adjustment in the relative axial positions of the outer and inner housings 108, 109 such that the engagement projection 120 is axially displaced along the axial slot 124 generally to the intersection of the axial slot 124 and the first transversal slot 122a. Additionally, such an axial adjustment can facilitate adjustment of the relative axial positions of the latch bolt 166 and the latch bar 168 such that the bolt fastener 184 is positioned within the adjustment recess 198 at a location that is adjacent to the first retention recess 202.
The face plate 162 and/or back plate 160 can then be rotatably displaced in a second rotation direction that is opposite of the first rotation direction. Such rotational displacement in the second rotation direction can facilitate a change in the relative angular positions of the outer and inner housings 108, 109 such that the engagement projection 120 is displaced from the axial slot 124 and along the first transversal slot 122a until the engagement projection 120 reaches the first end 128 of the first transversal slot 122a. Additionally, such rotation of the face plate 162 and/or back plate 160 in the second rotation direction can facilitate similar rotational displacement of the latch bolt 166, which can result in the bolt fastener 184 being displaced into the first retention recess 202. Further, as previously discussed, according to the illustrated embodiment, changes in the relative angular positions of the outer and inner housings 108, 109 can also result in engagement between the retention projection 154 of the outer housing 108 from the first aperture 156a of the inner housing 109 that can at least assist in retaining the relative positions of the outer and inner housings 108, 109.
The first body 188″ of the latch bar 168″ can generally extend along a pair of opposing sidewalls 187a, 187b. In the illustrated embodiment, at least one of the sidewalls 187a, 187b, such as, for example, a first sidewall 187a, can include a projection or fastener 184″ that extends away from at least a portion of the first sidewall 187a. According to the illustrated embodiment, the projection is generally defined by a first wall 177a and a second wall 177b that are generally oriented in divergent directions relative to each other. The projection 184″ can be positioned at a variety of locations along the first body 188″. For example, according to the illustrated embodiment, the projection 184″ can be toward the first end 180″ of the first body 188″ and in generally close proximity to, or extend from, an upper wall 183″ of the first body 188″. Further, the first side 187a can include a recess 189 that can provide a clearance that is sized to prevent interference between the latch bar 168″ and the bolt 166″ in the adjacent area around the projection 184″.
According to the embodiment shown in
According to certain embodiments, the bolt biasing element 174 may exert a biasing force that biases the latch bolt 166 to the extended, locked position. According to the illustrated embodiment, a first end 227 of the bolt biasing element 174 may exert a force against a backside 228 of the latch bolt 166. Further, according to certain embodiments, at least a portion of the bolt biasing element 174 around the first end 226 can be positioned about a hub 230 that extends from a backside 228 of the latch bolt 166 that can at least assist in retaining a position of the bolt biasing element 174. Further, a second end 232 of the bolt biasing element 174 can abut against a back wall 234 at the second end 232 of the outer housing 108.
Referencing
Upon removal of the force(s) that rotatably displaced the doorknob or lever, and thus was used to rotate the cam(s) 176 in the first direction, the biasing force of the bolt biasing element 174 can facilitate the return the latch bolt 166 from the unlocked, retracted position, to the locked, extended position. According to the illustrated embodiment, as the latch bolt 166 can be coupled to the latch bar 168 via the bolt fastener 184 extending from the latch bolt 166 and into the first or second retention recess 202, 204, such axial displacement of the latch bolt 166 can result in similar axial displacement of the latch bar 168. Further, as the latch bar 168 is axially displaced generally in a direction toward the first end 210a of the latch assembly 100, the latch bar 168 can exert a force against the multiplier link 170 that facilitates the rotation of the multiplier link 170 in a second rotational direction that is opposite of the first rotational direction. For example, the multiplier link 170 can be rotatably displaced in the second direction such that the multiplier link 170 is rotated from the retracted second position (
According to the illustrated embodiment, the latch assembly 100 can include two split cams 176, one cam 176 being adjacent to a first side portion 236a of the cover housing 208 and another cam 176 being adjacent to an opposing second side portion 236b of the cover housing 208. The use of a pair of split cams 176 can assist the latch assembly 100 in resisting twist load on a spindle when first and second doorknobs or levers that are on opposing sides of the latch assembly 100 are both rotated in opposite directions.
According to certain embodiments, the cams 176 can each be configured to be positioned about an inwardly extending hub of the corresponding first and second side portions 236a, 236b of the cover housing 208, which can at least assist in guiding the rotational displacement of the cams 176 about a cam axis 238 (
Each cam 176 can include a body portion 242 and a foot portion 244. According to the illustrated embodiment, the body portion 242, through which the aperture 240 of the cam 176 extends, can have a generally circular, cylindrical, and/or ring shape, among other shapes. The foot portion 244 can outwardly extend from the body portion 242, and include a first side 246a and a second side 246b. Further, the first side 246a and/or the second side 246b of the foot portion 244 can be structured to extend to a position in which the first side 246a and/or the second side 246b of the foot portion 244 can selectively engage the latch link 172, as discussed below, as well as not interfere with the rotational displacement of the multiplier link 170.
Referencing
As discussed below, rotation of one or both of the cams 172 in the first rotational direction can result in the foot portion 244 of the cam(s) 172 contacting the lower segment 250 of the latch link 172 in a manner that facilitates linear displacement of the latch link 172 in a first direction generally toward the first end 210a of the latch assembly 100. Such linear displacement of the latch link 172 can facilitate a the lower end wall 254 of the latch link 172 exerting a pushing or pulling force on at least a lower section 258 of the multiplier link 170 that facilitates the rotation of the multiplier link 170 in the first rotational direction. Further, the second body 190 of the latch bar 168 can be coupled to the upper section 256 of the multiplier link 170, such as, for example, via insertion of at least a portion of the upper section 256 of the multiplier link 170 in the aperture 193 of the latch bar 168. According to such an embodiment, rotation of the multiplier link 170 can facilitate the upper section 256 of the multiplier link 170 exerting a pushing or pulling force that linearly displaces the latch bar 168, and thus the latch bolt 166, in a second direction generally toward the second end 210b of the latch assembly 100, thereby displacing the latch bolt 166 from the extended position and toward, and/or to, the retracted position.
According to certain embodiments, the lower sections 258 of the multiplier link 170 include one or more curved or inclined surfaces that engage mating curved or inclined surfaces of the lower end wall 254 of the latch link 172 and the portions of the latch bar 168 that generally define the aperture 182 of the latch bolt 168 in a manner that, at least when the latch bolt 166 is being displaced from the extended position, facilitates the translation of linear movement of the latch link 172 to rotational displacement of the multiplier link 170, and rotational displacement of the multiplier link 170 to linear displacement of the latch bar 168.
Referencing
According to certain embodiments, the multiplier axis 267 can be offset from a midsection of the multiplier link 170, such as, for example, being closer to the lower section 258 than the upper section 256 of the multiplier link 170. Moreover, according to certain embodiments, the multiplier axis 267 can be at a location relative to the cam 176 such that the multiplier axis 267 is below, or offset from, the cam axis 238. For example, according to certain embodiments, the cam axis 238 may generally intersect or be relative close proximity to, a central longitudinal axis 268 of the latch assembly 100, while the multiplier axis 267 is offset, or at a different distance from, the central longitudinal axis 268. Such a configuration can assist in amplifying the rotational displacement of the handle such that a relatively small degree of rotation of the handle can result in the retracted of an extended latch bolt 166. For example, such retraction of the latchbolt may result from rotating the handle through an angle between about 42 degrees to about 48 degrees, and moreover about 45 degrees, among other rotational angles. Moreover, by offsetting the multiplier axis 267 from the cam axis 238, the rotational displacement of the multiplier link 170 via the linear displacement of the latch link 172 can increase the angular rotation of the multiplier link 170. For example, according to certain embodiments, the multiplier link 170 can, for example, be pivotally displaced about 70 degrees between the extended position (
According to the illustrated embodiment, the upper section 256 of the multiplier link 170 is configured to be received in an aperture 182 in the latch bar 168, as demonstrated by at least
According to the illustrated embodiment, as shown in at least
Referencing
When the force that was applied to rotate the doorknob or lever is removed, biasing forces of the latch assembly 100 (including, for example, the biasing force of the bolt biasing element 174) can at least assist in displacing the latch bolt 166 back to the extended, locked position. Such displacement can also facilitate similar displacement of the latch bar 168, which can exert a force against the front wall 262a of the multiplier link 170 that facilitates the rotation of the multiplier link 170 in a second direction that is opposite of the first rotational direction (R1). Such rotation of the multiplier link 170 can also facilitate the lower section 258 of the multiplier link 170 exerting a force against the lower segment 250 (such as, for example, the lower end wall 254), which facilitates the displacement of the latch link 172 in a direction toward the second end 210b of the latch assembly 100. According to certain embodiments, such displacement of the latch link 172 can also be facilitated by the cam 176 being directly or indirectly biased to a neutral position, as shown in
Referencing
The dead latch link 142 can have a variety of shapes and configurations. For example, referencing
According to the illustrated embodiment, one of the first and second arms 276, 278 includes a pair of bends 288a, 288b while the other of the first and second arms 276, 278 includes one bend 288c. According to the illustrated embodiment, a first bend 288a of the first arm 276 is positioned for use when the latch assembly 100 is at the first backset setting, and a second bend 288b of the first arm 276 that is positioned for use when the latch assembly 100 is at the second backset setting. Referencing
According to certain embodiments, the dead latch link 142 can be coupled to the cover housing 208 in a manner that forms a pivot or hinge about which the dead latch link 142 can be tilted between the dead-latching position and the release position. For example, according to the illustrated embodiment, the dead latch link 142 includes first and second legs 296a, 296b that extend from a second side 284b of the base portion 280, and which are generally parallel to each other. Additionally, the first and second arms 276, 278 are separated from each other to form an opening 298 that is sized to receive an extension 300 of the cover housing 208, as shown in at least
When in the dead-latching position, as shown, for example, in at least
The plunger 272 can also have a variety of shapes and configurations. For example,
According to certain embodiments, a hub 312 may extend from a back wall of the main body 306, the hub 312 being sized to at least assist in retaining a position of the plunger biasing element 274. More specifically, according to the illustrated embodiment, a first end of the plunger biasing element 274 can be positioned about the hub 312 of the plunger 272, while an opposing second end of the plunger biasing element 274 is positioned about a projection 314 that extends from the base portion 280 of the dead latch link 142. According to such an embodiment, the plunger biasing element 274 can provide a force that seeks to bias the plunger 272 to the extended position such that the plunger 272 can, at least in certain circumstances, outwardly extend with the latch bolt 166 when the latch bolt 166 is at an extended, locked position.
The plunger 272 can also include a plunger arm 316, which can extend from the back wall of the main body 306 of the plunger 272. Additionally, as shown in at least
According to the illustrated embodiment, the plunger arm 316 may extend from the main body 306 in a linear direction that is generally parallel to a central longitudinal axis of the plunger 272. Further, a distal end 320 of the plunger arm 316 may include a plunger finger 322 that generally extends in a direction that is non-parallel to the plunger arm 316. For example, according to the illustrated embodiment, the plunger finger 322 can be generally orthogonal relative to the plunger arm 316. Further, according to certain embodiments, the plunger finger 322 can be positioned to engage the bends 288a, 288b, 288c of the first and/or second arms 276, 278 of the dead latch link 142 in a manner that can facilitate the tilting of the dead latch link 142 between the dead-latching position and a release position. According to the illustrated embodiment, the plunger finger 322 is positioned to engage the single bend 288c of the second arm 278, and not the bends 288a, 288b of the first arm 276, of the dead latch link 142 in a manner that can facilitate the tilting of the dead latch link 142 to the dead-latching position.
According to certain embodiments, during use, when the latch bolt 166 is in an extended, locked position, the dead latch link 142 can be in the dead-latching position so as to block displacement of the latch bolt 166 to the retracted, unlocked position. In such a situation, a user can rotate a lever or doorknob so as to facilitate the rotational displacement of one of the cams 176. As previously discussed, such rotation of the cam 176 can facilitate the linear displacement of the latch bar 168, which can, depending on whether the latch assembly 100 is at the first or second backset setting, bring the extension 294 into contact with the first or the second bend 288a, 288b in a manner that can facilitate the dead latch link 142 being tilted to the release position, as shown in at least
As previously discussed, with the dead latch link 142 in the tilted position and the latch bolt 166 being retracted, a portion of the plunger 272 can be engaged, or positioned to be engaged, with the latch bolt 166 (such as, for example, the plunger arm 316 being engaged with the latch bolt 166), such that the plunger 272 is also linearly displaced with the latch bolt 166 toward the second end 210b of the latch assembly 100. Further, according to certain embodiments, the plunger 272 can be displaced to a position within the latch assembly 100 such that the latch bolt 166 does not protrude, or protrudes in a relatively small amount, out from the face plate 162 of the latch assembly 100. Additionally, as the plunger 272 is displaced toward the second end 210b of the latch assembly 100, the plunger finger 322 can be displaced into engagement with the bend 288c in the second arm 278 of the dead latch link 142, as shown in at least
Conversely, when the latch bolt 166 is being displaced from the retracted position to the extended position (i.e., by the biasing force of the bolt biasing element 174), the plunger 272 can at least initially remain within the latch assembly 100. According to such an embodiment, while the latch bolt 166, and thus the latch bar 168, is linearly displaced toward the extended position, the extension 294 of the latch bar 168 may move away from being in contact with at least the land 292 of the first and second bends 288a, 288b. However, as the position of the plunger 272 is generally at least temporarily retained, the plunger finger 322 can remain engaged with the bend 288c of the second arm 278 such that the dead latch link 142 remains in the release position. According to the illustrated embodiment, when the back wall 304 and/or recesses 302 of the latch bolt 166 are positioned to receive placement of, and/or be adjacent to, at least the first ends 282a of the first and second arms 276, 278 of the dead latch link 142, the midsection 192 of the latch bar 168 may engage the plunger 272 in a manner that generally linearly displace the plunger 272 to an extended position. Such displacement of the plunger 272 can disengage the plunger finger 322 from the bend 288c of the second arm 278 such that the dead latch link 142 returns to the dead-latching position.
The plunger 272′ has a main body 306′ and an arm 340. The main body 306′ extends between a first end 324a and a second end 342b, and can include a cavity 344 that is sized to receive insertion of at least a portion of a first biasing element 326a. Moreover, a first end of the first biasing element 326a can be positioned to abut a wall 346 at or near an end of the cavity 344 and/or be positioned about a hub that extends from the wall 346. The arm 340 can extend from a portion of the second end 342b of the main body 306′ (i.e., a corner and/or side of the main body 306′), and includes an upper wall 348 and a recessed section 350 that is configured to at least assist with, and/or not interfere with, the tilting of the dead latch link 142′ between the dead-latching position and the release position. For example, according to the illustrated embodiment, the recessed section 350 can be a generally inwardly-curved or convex surface that can engage at least a portion of a mating, generally outwardly-curved or concave surface of the protrusion 330. According to certain embodiments, the arm 340 can be offset from a central longitudinal axis of the main body 306′.
As illustrated in at least
As shown in
According to certain embodiments, depending on whether the latch assembly 100 is set for the first backset setting or the second backset setting, with the dead latch link 142′ in the dead-latching position, the protrusion 330 of the dead latch link 142′ can engage, or be adjacent to, the first or second abutment surfaces 224, 226 of the latch bar 168′. With the dead latch link 142′ in the dead-latching position, rotation of a lever or doorknob that is coupled to the latch assembly 100 can, as previously discussed, facilitate the displacement of the latch bar 168′ toward the second end 210b of the latch assembly 100. As the latch bar 168′ is linearly displaced in the general direction of the second end 210b of the latch assembly 100, the shape(s) of the protrusion 330 of the dead latch link 142′ and/or of the engaged first or second abutment surfaces 224, 226 of the latch bar 168′ can facilitate the lifting of at least the protrusion 330 of the dead latch link 142′ such that the dead latch link 142′ is tilted to the release position. With the dead latch link 142′ in the release position, the dead latch link 142′ may be moved to a location at which the dead latch link 142′ does not interfere with the displacement of the latch bar 168′, and thus the latch bolt 166′, to the retracted position.
When the latch bolt 166′ subsequently returns from the retracted position to the extended position, the latch bar 168′ can be displaced in a manner that linearly displaces the latch bolt 166′ to the extended position. During such displacement, the plunger 272′ can, at least temporarily, remain in a retracted position in the latch assembly 100 at least until a biasing force of the first and/or second biasing elements 326a, 326b displaces the plunger to the extended position. As the plunger 272′ returns to the extended position, the relative positions of the plunger 272′ and the dead latch link 142′ can change such that the dead latch link 142′ is positioned adjacent to the upper wall 348 of the arm 340, thereby facilitating the dead latch link 142′ to be tilted to the release position.
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment(s), but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures as permitted under the law.
Furthermore it should be understood that while the use of the word preferable, preferably, or preferred in the description above indicates that feature so described may be more desirable, it nonetheless may not be necessary and any embodiment lacking the same may be contemplated as within the scope of the invention, that scope being defined by the claims that follow. In reading the claims it is intended that when words such as “a,” “an,” “at least one” and “at least a portion” are used, there is no intention to limit the claim to only one item unless specifically stated to the contrary in the claim. Further, when the language “at least a portion” and/or “a portion” is used the item may include a portion and/or the entire item unless specifically stated to the contrary.
The present application is a continuation of U.S. patent application Ser. No. 16/726,478 filed Dec. 24, 2019 and issued as U.S. Pat. No. 11,236,527, which is a continuation of U.S. patent application Ser. No. 15/466,283 filed Mar. 22, 2017 and issued as U.S. Pat. No. 10,513,872, which claims the benefit of U.S. Provisional Patent Application No. 62/312,211 filed Mar. 23, 2016, the contents of each application incorporated herein by reference in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
2592573 | Joncas | Apr 1952 | A |
2795447 | Schlage | Jun 1957 | A |
4711477 | Fann | Dec 1987 | A |
4746154 | Fang | May 1988 | A |
4767140 | Lin | Aug 1988 | A |
4974883 | Jans | Dec 1990 | A |
5152558 | Smith | Oct 1992 | A |
5257837 | Bishop | Nov 1993 | A |
5498037 | Fan Lai | Mar 1996 | A |
5501492 | Kajuch | Mar 1996 | A |
5570912 | Mullich | Nov 1996 | A |
5647617 | Kajuch | Jul 1997 | A |
6419288 | Wheatland | Jul 2002 | B1 |
6612627 | Wheatland | Sep 2003 | B2 |
7497486 | Davis | Mar 2009 | B1 |
8360482 | Viviano | Jan 2013 | B2 |
8864186 | Kondratuk | Oct 2014 | B2 |
Number | Date | Country | |
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20220364391 A1 | Nov 2022 | US |
Number | Date | Country | |
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62312211 | Mar 2016 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16726478 | Dec 2019 | US |
Child | 17590458 | US | |
Parent | 15466283 | Mar 2017 | US |
Child | 16726478 | US |