The present invention relates generally to latches, and particularly, to compression latches that can be used for securing storage compartments and can provide a clear indication regarding the latched or unlatched state of the latches.
Conventionally, storage compartments in restricted areas (such as commercial, rail, or medical environments for example) must be secured to prevent unauthorized access to their contents. Latches may be used to restrict access to such compartments to users having a corresponding key. In many latches, it may not be clearly visible to the user whether the latch is in an opened or closed position. For such latches, it may be advantageous to provide an indication regarding whether the latch is in a latched or unlatched state.
Aspects of the present invention are related to latches.
According to one aspect of the invention, a latch is configured to fix a panel relative to a frame. The latch includes a housing configured for engagement to the panel, the housing having a longitudinal axis and defining an aperture along the longitudinal axis; a cap mounted within the aperture of the housing for rotation about the longitudinal axis, the cap comprising a drive surface for rotating the cap relative to the housing between a latched position and an unlatched position; and a cover coupled to the housing to pivot about a lateral axis different from the longitudinal axis, the cover pivotable to be in a closed position in which the cover covers the cap, the cover comprising an engagement surface spaced from the lateral axis; wherein when the cap is in the unlatched position, the drive surface of the cap is aligned with the engagement surface of the cover and positioned to block the cover from pivoting to the closed position; and wherein when the cap is in the latched position, the drive surface of the cap is unaligned with the engagement surface of the cover and positioned to permit the cover to pivot to the closed position.
The cap can include a drive stud extending along the longitudinal axis and forming the drive surface, and the drive surface can include a recess defined in the drive stud. Also, the cap can define a drive opening extending in a direction along the longitudinal axis and forming at least a portion of the drive surface, and the drive surface can include a recess defined in a wall of the drive opening. The engagement surface can be defined by a protrusion extending from a surface of the cover facing the cap when the cover is in the closed position.
The latch can include a hinge extending along the lateral axis. The hinge can include a first cam fixed against rotation relative to the housing, a second cam fixed against rotation relative to the cover, and a spring biasing the first and second cams to contact one another. The first and second cams can each comprise first and second cam surfaces, wherein contact between the first cam surfaces generated by the spring biases the cover to rotate in a direction toward the closed position, and wherein contact between the second cam surfaces generated by the spring cases the cover to rotate in a direction away from the closed position.
The latch can also include a pawl coupled to the cap, the pawl being configured to engage the frame. Also, the latch can include a shaft extending along the longitudinal axis within the aperture of the housing, the shaft being mounted for rotation about the longitudinal axis, the shaft further being mounted for axial movement relative to the cap; a spring configured to bias the shaft away from the cap along the longitudinal axis; a sleeve interposed between the shaft and the housing, the sleeve defining a first slot; a cam interposed between the shaft and the housing, the cam being rotatable relative to the sleeve about the longitudinal axis, the cam defining a second slot; and a pin extending radially outwardly from the shaft relative to the longitudinal axis, the pin extending into the first and second slots, wherein the first and second slots are configured to guide the rotation and axial movement of the shaft as the cap is rotated within the housing such that the pawl engages or disengages the frame.
According to another aspect of the invention, a latch is configured to fix a panel relative to a frame, the latch including a housing configured for engagement to the panel, the housing having a longitudinal axis and defining an aperture along the longitudinal axis; a cap mounted within the aperture of the housing for rotation about the longitudinal axis, the cap comprising a drive stud for rotating the cap relative to the housing between a latched position and an unlatched position, a recess being defined in the drive stud; a base rigidly coupled to the housing; a lid coupled to the base to pivot about a lateral axis different from the longitudinal axis, the lid pivotable to be in a closed position in which the lid covers the cap, the lid comprising a protrusion extending from a surface of the cover facing the cap when the cover is in the closed position; and a hinge extending along the lateral axis and coupling the lid to the base, the hinge comprising a first cam fixed against rotation relative to the base, a second cam fixed against rotation relative to the lid, and a spring biasing the first and second cams to contact one another, wherein when the cap is in the unlatched position, the recess of the cap is unaligned with the protrusion of the lid and the drive stud is positioned to block the lid from pivoting to the closed position; and wherein when the cap is in the latched position, the recess of the cap is aligned with the protrusion of the lid and the drive stud positioned to permit the lid to pivot to the closed position.
The first and second cams can each comprise first and second cam surfaces, wherein contact between the first cam surfaces generated by the spring biases the lid to rotate in a direction toward the closed position, and wherein contact between the second cam surfaces generated by the spring cases the lid to rotate in a direction away from the closed position.
According to yet another aspect of the invention, a compartment includes a frame; a panel mounted for movement relative to the frame between opened and closed positions; and a latch coupled to the panel, the latch being positioned to fix the panel relative to the frame in the closed position, the latch including a housing engaged to the panel, the housing having a longitudinal axis and defining an aperture along the longitudinal axis; a cap mounted within the aperture of the housing for rotation about the longitudinal axis, the cap comprising a drive surface for rotating the cap relative to the housing between a latched position and an unlatched position; and a cover coupled to the housing to pivot about a lateral axis different from the longitudinal axis, the cover pivotable to be in a closed position in which the cover covers the cap, the cover comprising an engagement surface spaced from the lateral axis; wherein when the cap is in the unlatched position, the drive surface of the cap is aligned with the engagement surface of the cover and positioned to block the cover from pivoting to the closed position; and wherein when the cap is in the latched position, the drive surface of the cap is unaligned with the engagement surface of the cover and positioned to permit the cover to pivot to the closed position.
The housing can define a recess extending radially outwardly from the longitudinal axis of the housing and the cover includes a housing engagement surface positioned to extend into the recess when the cover is in the closed position, and the housing engagement surface can extend from the engagement surface. Also, the engagement surface and the housing engagement surface can inhibit relative rotation of the cap and the housing when the cover is in the closed position. The latch can also include a base fixed against rotation relative to the housing, the cover being pivotally connected to the base. Additionally, the latch can include a recess defined on the cover or on the base for engagement with a protrusion on the base or on the cover, the recess and the protrusion being positioned to resist rotation of the cover relative to the housing when the cover is in the closed position, and the recess can be defined on the cover and the protrusion can be on the base.
The invention is best understood from the following detailed description when read in connection with the accompanying drawings. It is emphasized that, according to common practice, the various features of the drawings are not to scale. On the contrary, the dimensions of the various features may be arbitrarily expanded or reduced for clarity. Included in the drawings are the following figures:
Although the invention is illustrated and described herein with reference to specific embodiments, the invention is not intended to be limited to the details shown. Rather, various modifications may be made in the details within the scope and range of equivalents of the claims and without departing from the invention.
The exemplary latches described herein may have a lower profile than conventional latches for storage compartments in that they can provide for a reduction of the degree of the protrusion of the latch into such compartments, decreasing or eliminating the effect of the latch on available storage space. These embodiments generally incorporate a latch cap and shaft which rotatably and/or axially move to open or close the compartment.
The exemplary latches described herein may also be capable of providing a clear indication regarding whether the latch is in a latched or unlatched state. These latches may employ a cover that functions both to provide the indication and protect internal features of the latch from moisture or dirt present in an external environment of the latch. This indication may be helpful to prevent accidental or unintentional removal of a latch key before the latch is completely latched or unlatched.
In examples set forth below, the latch cover cannot be fully closed until the latch is in the latched position. Preventing the cover from closing may serve as a reminder to lock compartments, and may promote a methodical opening and closing sequence of latches. During the unlatching sequence, the cap of the latch rotates out of alignment with an engagement structure on the latch cover. As a result, when in an unlatched position, it is not possible to close the cover. The sequence is reversed in the latching operation, allowing the cover to be closed only when the cap has returned to the latched position.
While particular latch embodiments are described herein, components of the disclosed embodiments may be incorporated into any conventional latches known to one of ordinary skill in the art to achieve the advantages described herein. For example, components of the disclosed embodiments may be incorporated into those latches described in PCT International Application No. PCT/US2016/041873 and/or U.S. Patent Application No. 62/413,080, the contents of each of which are incorporated herein by reference in their entireties. Likewise, the disclosed latches may be usable on any structure, including any type of storage compartments in which it is desirable to secure the contents of the compartment. The latch is preferably a compression latch for use with a panel mounted to a frame. Such a compression latch is configured for movement from an open position in which a panel is not latched relative to the frame, to a latched position in which the panel is latched relative to the frame, and to a locked position in which the panel is pulled against the frame such that they are compressed against one another.
Referring now to the drawings,
Housing 110 houses the components of latch 100. Housing 110 is configured for engagement to panel 10. In an exemplary embodiment, housing 110 has a body portion 112 and a flanged portion 114 extending circumferentially around an outer surface of body portion 112, as shown in
In a preferred embodiment, housing 110 engages with panel 10 using a nut 102. Nut 102 is adapted to be screwed onto threading formed on the outer surface of body portion 112, such that panel 10 is clamped between flanged portion 114 and nut 102. A washer 104 may be added between panel 10 and nut 102 to create an appropriate securement of latch 100 to panel 10. Additionally, a gasket (not shown) may be added between panel 10 and the flanged portion 114 of the housing 110 to secure the interior of the compartment from external elements such as moisture or dust. The use of nut 102 within the compartment to secure latch 100 to panel 10 desirably prevents unauthorized removal of latch 100 from panel 10.
Alternatively or additionally, housing 110 may engage with panel 10 by any other means, including for example a frictional or threaded fit of body portion 112 within the through-hole of panel 10, or adhering the flanged portion 114 to the surface of panel 10. For example, a fastener such as a screw can be used as can bracket mounting configurations. Still further, a portion or all of housing 110 may be formed as an integral or unitary piece with panel 10.
Body portion 112 of housing 110 extends along a longitudinal axis. The longitudinal axis generally extends in a direction orthogonal to the plane of panel 10. Nonetheless, it will be understood from the description herein that the longitudinal axis may extend at an oblique angle relative to panel 10, and the direction of the longitudinal axis is not intended to be limited. Body portion 112 of housing 110 further defines an aperture 116 therein which extends along the longitudinal axis. Aperture 116 is sized to accommodate the components of latch 100, as described below.
Housing 110 may further include at least one indicator 118, as shown in
Cap 120 is mounted at least partially within aperture 116 of housing 110. Cap 120 is not affixed to housing 110, so that it can rotate relative to housing 110 around the longitudinal axis. As shown in
Cap 120 may be prevented from axial movement relative to housing 110. In an exemplary embodiment, cap 120 includes a retainer 119 which surrounds an outer surface of cap 120 and which engages within a corresponding groove formed along the inner circumferential surface of housing 110. In a preferred embodiment, a gasket 121 such as an O-ring may be added between housing 110 and cap 120 in order to secure the interior of body portion 112 from external elements such as moisture or dust. Cap 120 and/or housing 110 may include an annular groove or surface for accommodating gasket 121 between cap 120 and housing 110.
Cap 120 includes at least one drive surface 122, as shown in
In one exemplary embodiment, cap 120 comprises a drive stud 126 extending from an upper surface of cap 120 along the longitudinal axis. Drive stud 126 may form the drive surface 122 for rotating cap 120. In an alternative or additional exemplary embodiment, cap 120 comprises a drive opening extending into an upper surface of cap 120 along the longitudinal axis. This drive opening may also form the drive surface 122 for rotating cap 120.
Cap 120 may further include at least one recess 124. Recess 124 is provided to enable closing of cover 200, as will be discussed in greater detail below. Recess 124 may also be provided to indicate to a user the rotational position of cap 120 relative to housing 110. In an exemplary embodiment, recess 124 is positioned to align with a corresponding indicator 118 on housing 110 to indicate to the user when cap 120 is in the latched (secured) position.
In an embodiment in which drive surface 122 of cap 120 is formed by drive stud 126, recess 124 may be defined in an upper surface or a wall of drive stud 126. Alternatively or additionally, in an embodiment in which drive surface 122 of cap 12 is formed by a drive opening, recess 124 may be defined in an upper surface or a wall of the drive opening.
Shaft 130 is mounted at least partially within aperture 116 of housing 110. Shaft 130 extends along the longitudinal axis of housing 110. Shaft 130 is mounted to be rotatable around the longitudinal axis relative to housing 110 and cap 120. Shaft 130 may have a circular shape in order to enable unobstructed rotation of shaft 130 within housing 110.
Shaft 130 is mounted to be axially movable relative to housing 110 and cap 120. In an exemplary embodiment, shaft 130 has a sliding engagement with cap 120 which defines the direction of the axial movement of shaft 130 relative to cap 120.
In an exemplary embodiment, shaft 130 includes a through-hole 134. Through-hole extends in the radial direction through the body of shaft 130. Through-hole 134 is shaped to accommodate a pin 170 passing through shaft 130, as described in further detail below.
Shaft 130 may further include threading 136 on a lower end thereof. Threading 136 is sized to accommodate a nut for affixing pawl 180, as described in further detail below.
Spring 140 is configured to bias shaft 130 away from cap 120 along the longitudinal axis. In an exemplary embodiment, spring 140 is a compression spring. The spring can include one or multiple elements, such as compression springs, wave springs, belleville washers, elastomeric springs, and/or conical springs. In an exemplary embodiment, spring 140 extends from a lower surface of cap 120 to a surface defined within a recess in a top of shaft 130, in order to reduce or further reduce the overall height of latch 100.
Sleeve 150 is positioned within aperture 116 interposed between housing 110 and shaft 130. Sleeve 150 thus defines an aperture in which shaft 130 is positioned.
Sleeve 150 is mounted within housing 110 in such a manner to prevent rotation of sleeve 150 relative to housing 110. In an exemplary embodiment, as shown in
Sleeve 150 defines a pair of slots 154. Slots 154 are sized to receive pin 170 therein, and to allow axial and/or rotational movement of pin 170 along each slot 154. In an exemplary embodiment, each slot 154 has an L-shape, with a first portion 154A extending in the longitudinal or axial direction of housing 110, and a second portion 154B extending in the circumferential direction of housing 110. The first and second portions 154A, 154B of each slot 154 guide the movement of shaft 130 within housing 110 during an opening or closing operation of latch 100, as described in greater detail below.
Cam 160 is positioned within sleeve 150 interposed between sleeve 150 and shaft 130. Cam 160 is mounted within sleeve 150 to be rotatable relative sleeve 150 around the longitudinal axis. In particular, cam 160 is mounted to be rotatable with cap 120. In an exemplary embodiment, as shown in
Cam 160 defines a pair of slots 164. Slots 164 are sized to receive pin 170 therein, and to allow axial and/or circumferential movement of pin 170 along each slot 164. In an exemplary embodiment, each slot 164 is spirally curved around the outer circumferential surface of cam 160 between a first position near cap 120 and a second position axially spaced from the first position away from cap 120. With slots 154, slots 164 guide the movement of shaft 130 within housing 110 during an opening or closing operation of latch 100, as described in greater detail below.
While cam 160 is described as being positioned within sleeve 150, it will be understood that the invention is not so limited. Cam 160 could alternatively be positioned outside of sleeve 150, such that sleeve 150 is interposed between cam 160 and shaft 130, without departing from the scope of the invention.
Additionally, while cam 160 is described as being a separate component from cap 120, it will be understood that the invention is not so limited. Alternatively, all or a portion of cam 160 could be formed integrally or as a unitary piece with cap 120. Such a structure may be desired in order to further minimize the overall protrusion P of latch 100.
Pin 170 extends radially outward from shaft 130 relative to the longitudinal or axial direction of housing 110. Pin 170 is captured within an aperture formed in the shaft 130, and is received with slots 154 and 164. As a result, shaft 130 is limited to moving rotationally or axially within the path defined by the engagement of pin 170 with slots 154 and 164.
In an exemplary embodiment, pin 170 is a cylindrical post extending diametrically through through-hole 134 of shaft 130. The post has a length sufficient to form diametrically opposed projections on either side of shaft 130. In this embodiment, sleeve 150 and cam 160 may each include a pair of diametrically opposed slots 154 and 164 on either side thereof. Accordingly, while the operation of latch 100 is described herein with respect to a single slot 154, 164 and pin 170, it will be understood by one of ordinary skill in the art that one, two, or more respective slots and pins may be used without departing from the scope of the invention.
Pawl 180 is coupled indirectly to cap 120 to rotate with cap 120. In an exemplary embodiment, pawl 180 is fixedly coupled to the lower end of shaft 130 via one or more nuts that are engaged with threading 136 on either or both sides of pawl 180. Alternatively, pawl 180 may be fixedly coupled to the lower end of shaft 130 via a screw which engages with internal threading on shaft 130. A washer 184 may be added between the nut(s) and pawl 180 to create an appropriate securement of pawl 180 to shaft 130.
Pawl 180 is rotatable between a latched position and an unlatched position during rotation of cap 120. Pawl 180 is moved between the latched position and the unlatched positioned by rotation and axial movement of shaft 130 during rotation of cap 120.
Cover 200 is coupled to housing 110. Cover 200 is configured to pivot about a lateral axis between an open position, as shown in
In an exemplary embodiment, cover 200 includes a base 210, a lid 220, and a hinge 230. Base 210 is configured to be rigidly coupled to housing 110. As shown in
While base 210 is described herein as a being a separate component from housing 110, it will be understood that the invention is not so limited. In other embodiments, base 210 could be integrally formed with housing 110, and/or the components of base 210 can be provided on the outer surface of housing 110.
Base 210 may also include a structure designed to mate with and/or hold lid 220 in place when cover 200 is in the closed position. In an exemplary embodiment, base 210 includes a detent 215 extending outwardly from base portion 212. Detent 215 may project outwardly from base portion 212 at a portion of base portion 212 opposite extending portion 214, as shown in
Lid 220 is coupled to base 210. Lid 220 is coupled to pivot relative to base 210 about lateral axis 216. Lid 220 can pivot between the open position and the closed position in which lid 220 covers cap 120. As shown in
When a detent 215 is provided, lid 220 may include a recess 225. Recess 225 is positioned to align with detent 215 when cover 200 is in the closed position. As shown in
An engagement surface 226 is provided on the lower surface 224 of lid 220. Engagement surface 226 may be spaced from lateral axis 216 of base 210 in order to better align with cap 120. Engagement surface 226 aligns with cap 120 when cap 120 is rotated to be in the latched position, to allow closing of cover 200. Engagement surface 226 may be spaced from lateral axis 216 of base 210 in order to better align with cap 120. In an exemplary embodiment, engagement surface 226 is defined by a protrusion extending from lower surface 224 toward cap 120.
A pad 228 may further be provided on the lower surface 224 of lid 220. Pad 228 may be provided to create an environmental seal for protecting internal features of latch 100 (such as cap 120, shaft 130, etc.) from moisture or dirt present in an external environment of latch 100. Pad 228 may also include one or more visual indicators to allow a user to easily see when lid 220 is in the open position. Such visual indicators may include, for example, bright colors, reflective surfaces, or other similar elements. Suitable materials for forming pad 228 will be known to one of ordinary skill from the description herein.
Hinge 230 couples lid 220 to base 210. Hinge 230 is provided along lateral axis 216. In one embodiment, hinge 230 may be a simple pin hinge which allows unbiased pivoting of lid 220 relative to base 210. In other embodiments, however, hinge 230 may provide unidirectional or bidirectional bias to lid 220 depending on the position of lid 220 relative to base 210. For example, a torsion spring may optionally be used to provide unidirectional biasing of hinge 230 in a predetermined direction.
In an exemplary embodiment of bidirectional bias, hinge 230 comprises a first cam 232 and a second cam 234. Cam 232 is fixed against rotation relative to lid 220, and cam 234 is fixed against rotation relative to base 210. In other words, cam 232 is rotationally fixed with lid 220, and cam 234 is rotationally fixed base 210. As shown in
Cams 232 and 234 are biased into contact with one another by spring 238. In a particular embodiment, spring 238 is a coil spring. As shown in
While spring 238 is shown pressing against a rear surface of cam 234, it will be understood that this orientation is not intended to be limiting. In other embodiments, spring 238 may instead press cam 232 against 234 without departing from the scope of the present invention. Additionally, while spring 238 is shown as a coil spring, other springs suitable for use as spring 238 will be known to one of ordinary skill in the art from the description herein.
As set forth above, hinge 230 may provide bidirectional bias to lid 220 depending on the position of lid 220 relative to base 210. In one such embodiment, cam 232 includes first and second cam surfaces 233a and 233b, and cam 234 includes first and second cam surfaces 235a and 235b. Contact between cam surfaces 233a and 235a generated by spring 238 may bias lid 220 to rotate in a direction toward the closed position, and contact between cam surfaces 233b and 235b generated by spring 238 may bias lid 220 to rotate in a direction toward the open position.
An exemplary operation of latch 100 is described below with respect to
While the exemplary embodiment in
An exemplary closing operation of cover 200 of latch 100 is described below with respect to
When cap 120 is in the unlatched position, the drive surface 122 of cap 120 is aligned with the pivoting movement of the engagement surface 226 of cover 200, and thereby is positioned to block cover 200 from pivoting to the closed position. As shown in
As set forth above, hinge 230 may provide bidirectional bias. In an exemplary embodiment, cam surfaces 233a and 235a contact each other up until the point at which the protrusion defining engagement surface 226 enters recess 124 of cap 120, at which point cam surfaces 233b and 235b contact one another. Accordingly, as long as cover 200 is blocked from being pivoted to a position at which the protrusion enters recess 124 of cap 120, cams 232 and 234 of hinge 230 bias lid 220 to move toward the open position of cover 200, as shown by arrow in
Another exemplary closing operation of cover 200 of latch 100 is described below with respect to
When cap 120 is in the latched position, the drive surface 122 of cap 120 is unaligned with the pivoting movement of the engagement surface 226 of cover 200, and thereby is positioned to permit cover 200 to pivot to the closed position shown in
As explained above, cam surfaces 233a and 235a may contact each other up until the point at which the protrusion defining engagement surface 226 enters recess 124 of cap 120, at which point cam surfaces 233b and 235b contact one another. Accordingly, as soon as cover 200 is pivoted to a position at which the protrusion enters recess 124 of cap 120, cams 232 and 234 of hinge 230 bias lid 220 to move toward the closed position, as shown by arrow in
The bidirectional bias provided by hinge 230 may not be limited to being provided between the open and closed positions of lid 220. As shown by arrows in
As shown in
A recess 322 is provided in a drive surface of cap 320, and an engagement surface 334 is provided on a lower surface of lid 332. As shown in
In addition to engaging with cap 320, cover 330 may also engage with housing 310. A recess 312 is provided in housing 310. As shown in
Providing multiple engagement surfaces 334 and 336 may be useful to accomplish multiple purposes including preventing closing of cover 330 when cap 320 is in the unlatched position, as well as preventing rotation of cover 330 relative to cap 320 or housing 310 when cover 330 is in the closed position.
While preferred embodiments of the invention have been shown and described herein, it will be understood that such embodiments are provided by way of example only. Numerous variations, changes and substitutions will occur to those skilled in the art without departing from the spirit of the invention. Accordingly, it is intended that the appended claims cover all such variations as fall within the spirit and scope of the invention.
This patent application is a U.S. National Phase Patent Application of PCT Application No.: PCT/US2017/065038, filed Dec. 7, 2017, which claims priority to U.S. Provisional Application No. 62/431,677, entitled LATCH HAVING COVER, filed on 8 Dec. 2016, the contents of which are incorporated herein by reference in their entirety for all purposes.
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