The present invention relates generally to latches, and particularly, to compression latches that can be used for securing storage compartments and can provide for reduced protrusion of the latches into such compartments.
Conventionally, storage compartments in restricted areas (such as 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.
Depending on the environment or intended use, many storage compartments may have a united amount of available space, or may store objects that take up substantially all of the space within the compartment. For these types of compartments, it may be advantageous that the latch used for securing the compartment not unnecessarily protrude or impinge upon the limited space available. Accordingly, improved systems and devices are desired for securing storage compartments without negatively impacting available storage space yet while maintaining good latch performance.
Aspects of the present invention are related to latches.
According to one aspect of the invention, a latch is configured to fix a panel elative 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. The latch also includes a cap mounted within the aperture of the SEE housing for rotation about the longitudinal axis, the cap defining a longitudinally extending recess. Also included in the latch is 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, the shaft having a guide portion movably received in the recess of the cap. A spring of the latch is configured to bias the shaft away from the cap along the longitudinal axis, and a sleeve of the latch is interposed between the shaft and the housing, the sleeve defining a first slot. The latch also includes 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. A pin is provided extending radially outwardly from the shaft relative to the longitudinal axis, the pin extending into fs the first and second slots. The latch also includes a pawl coupled to the shaft, the pawl being configured to engage the frame. 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.
The cap can include a drive stud extending along the longitudinal axis and forming a drive surface for rotating the cap. If so, the recess of the cap can be at least partially defined within the drive stud.
The cap can also define a drive opening extending along the longitudinal axis and forming a drive surface for rotating the cap. If so, the recess of the cap can overlap with the drive opening in a radial direction of the cap, and the recess of the cap can extend to a position radially outward from the drive opening.
The spring can be positioned to surround the guide portion of the shaft, and the spring can extend between opposed surfaces of the shaft and the cap and have ends abutting the opposed surfaces. The opposed surface of the cap can be formed within the recess of the cap. The spring can include one or more of the following elements: compression springs, wave springs, belleville washers, elastomeric springs, and/or conical springs.
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 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 axially move to open or close the compartment.
While particular latch embodiments are described herein, components 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 it into those latches described in U.S. Pat. No. 4,583,775, the contents of which are incorporated herein by reference in their entirety. 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 sized to fit within a through-hole in panel 10. Housing 110 further includes a flanged portion 114 extending circumferentially around an outer surface of body portion 112. Flanged portion 114 is sized to contact an inner or outer surface of panel 10 when body portion 112 of housing 110 is received within the through-hole.
In a preferred embodiment, h sing 110 engages with panel 10 using a nut 102. Nut 102 is adapted to be screwed onto threading 115 formed on the outer surface of body portion 112, such that panel 10 s 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 liquid 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 an integral or unitary piece with panel 10.
Body portion 112 of housing 110 extends along a longitudinal axis. As shown in
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 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 121. Retainer 121 may be formed as a split ring which surrounds an outer surface of cap 120 Retainer 121 is accommodated within a groove 123 formed along the outer circumferential surface of cap 120 and a corresponding groove 113 formed along the inner circumferential surface of housing 110. When retainer 121 is seated within grooves 113 and 123, it prevents axial movement of cap 120 out of the aperture 116 defined by body portion 112.
In a preferred embodiment, a gasket such as an o-ring 106 may be added between housing 110 and cap 120 in order to secure the interior of body portion from external elements such as liquid or dust. Cap 120 and/or housing 110 may include all annular groove or surface for accommodating gasket 106 between cap 120 and housing 110.
Cap 120 includes at least one drive surface 122 on its upper surface, as shown in
Cap 120 further includes at least one longitudinally extending recess 124. Recess 124 is formed in a lower surface of cap 120, opposite drive surface 122. Recess 124 is formed to mate with a portion of shaft 130, as described below.
In one 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 this embodiment, recess 124 overlaps with drive stud 126 in the radial direction of housing 110. In other words, recess 124 is at least partially defined within drive stud 126.
Alternatively or additionally, cap 120 comprises a drive opening 128 extending into an upper surface of cap 120 along the longitudinal axis. Drive opening 128 may also form the drive surface 122 for rotating cap 120. In this embodiment, recess 124 overlaps with drive opening 128 in the radial direction of housing 110. In other words, recess 124 extends longitudinally to a position that is either radially outward from or radially inward from drive opening 128.
Overlap between recess 124 and the drive surface 122 of cap 120 is advantageous to lower the protrusion of latch 100. As set forth below, recess 124 is provided in order to define the direction of axial movement of shaft 130 during opening of latch 100. By creating a radial overlap between recess 124 and drive surface 122 (defined by drive stud 126 and/or drive opening 128), the overall height H of cap 120 (shown in
The embodiments illustrated in the figures are of a fixed grip style in which the position of the mounting of the pawl on the body of the latch is fixed in longitudinal position by the screw 182 and the housing 110. In other words, the position of the pawl cannot be easily adjusted by the user in this embodiment. In another embodiment having an adjustable grip feature, the position of the mounting of the pawl on the body of the latch can be adjusted using, for example, nuts to capture the position of the pawl at a user-selected position. A conventional latch having an adjustable grip feature may have a longer protrusion P of about 64 mm for example. This protrusion P can, for example, be reduced to about 54 mm according to an exemplary embodiment of this invention. In other words, protrusion P can be reduced by up to about 10 mm or even more for various latch configurations as compared to conventional latch designs.
As shown in
Cap 120 may further includes at least one indicator 125. Indicator 125 may be provided to indicate to a user the rotational location of cap 120 relative to housing 110. In an exemplary embodiment, indicator 125 is a notch which is positioned to align with a corresponding indicator 118 on housing 110 to indicate to the user when cap 120 is in the unrotated (secured) position.
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. As shown in
Shaft 130 is mounted to be axially movable relative to housing 110 and cap 120. In an exemplary embodiment, shaft 130 includes a guide portion 132. Guide portion 132 extends upward from shaft 130 in the axial direction toward cap 120
Guide portion 132 is sized to be received within recess 124 of cap 120. The sliding engagement of guide portion 132 within recess 124 defines the direction of the axial movement of shaft 130 relative to cap 120.
Shaft 130 further 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 further includes a threaded recess 136 in a lower end thereof. Threaded recess 136 is sized to accommodate a screw 182 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 positioned to surround guide portion 132 of shaft 130. The spring can include one or multiple elements, such as compression springs, wave springs, belleville washers, elastomeric springs, and/or conical springs. Spring 140 extends from a surface 127 on cap 120 to an opposing surface 138 on shaft 130, and has ends abutting the respective surfaces 127 and 138. In an exemplary embodiment, surface 127 of cap 120 is defined within recess 124, in order to reduce or further reduce the overall height H of cap 120.
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, sleeve 150 includes one or more keying features 152. positioned to mate with keying features 119 in housing 110. Keying features 152 and 119 may be detents, projections, recesses, or any other anti-rotation structures known to one of ordinary skill in the art from the description herein. Alternatively, all or a portion of sleeve 150 may be formed integrally or as a unitary piece with housing 110.
Sleeve 150 defines a pair of slots 154. Slots 154 are sized to receive pin 170 therein, and to allow axial and/or circumferential movement of pin 170 along each slot 154. In an exemplary embodiment, and referring to
Cam 160 is positioned within the aperture of 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, cam 160 includes one or more keying features 162 positioned to mate with keying features 129 in the lower surface of cap 120. Keying features 162 and 129 may be detents, projections, recesses, or any other anti-rotation structures known to one of ordinary skill in the art from the description herein.
Cam 160 defines a pair of slots 164. Slots 164 are sized to receive pill 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 cases 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 pins 170 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 to shaft 130. In an exemplary embodiment, pawl 180 is fixedly coupled to the lower end of shaft 130 via a screw 182 that is engaged with threaded recess 136. A washer 184 may be added between screw 182 and pawl 180 to create an appropriate securement of pawl 180 to shaft 130. Pawl 180 is movable between a closed position and an open position.
Pawl 180 is moved between the closed position and the open positioned by rotation and axial movement of shaft 130. In the closed position, shown in
An exemplary operation of latch 100 is described below with respect to
At this stage, in order to open latch 100, a user engages a key with drive surface 122 of cap 120 and begins rotating. Rotating cap 120 causes a corresponding rotation of cam 160, e.g., due to keying features 162 and 129. As cam 160 rotates, the spiral slot 164 of cam 160 applies a force to pin 170 in an axial and circumferential direction. The first portion of the L-shaped slot 154 allows movement of pin 170 in the axial direction, and prevents movement of pin 170 in the circumferential direction. As a result, rotation of cap 120 and cam 160 from the dosed position causes pin 170, and correspondingly shaft 130, to move only in the axial direction away from cap 120 (under bias from spring 140). This axial movement of shaft 130 moves pawl 180 axially downward and away from frame 20. The axial movement of pin 170 proceeds until pin 170 reaches the second portion of L-shaped slot 154.
While the exemplary embodiment in
An alternative cap 220 is illustrated in
Cap 220 further includes at least one longitudinally extending recess 124 formed in a lower surface of cap 220. Recess 124 includes a surface 127 therein which supports spring 140. Surface 127 of cap 120 is defined within recess 124, in order to reduce or further reduce the overall height H of cap 120.
Surface 127 includes an annular protrusion 227 in an inner edge thereof, as shown in
Cap 220 further includes keying features 229 in the lower surface of cap 220, as shown in
An alternative shaft 230 is illustrated in
Shaft 230 includes a guide portion 132 extending upward from shaft 130, as shown in
Shaft 230 includes a surface 138 which supports spring 140 when spring 140 surrounds guide portion 132. Guide portion 132 may further include a flared section 238 adjacent surface 138, as shown in
Steps of an alternate opening operation is illustrated in
Another alternative cap 320 is illustrated in
Cap 320 includes at least one drive surface 322 on its upper surface, as shown in
Cap 320 further includes at least one longitudinally extending recess 124 formed in a lower surface of cap 320. In this embodiment, there is no overlap between recess 124 and drive opening 328 in the radial direction of the housing. In other words, recess 124 extends longitudinally to a position that is either radially outward from or radially inward from drive opening 328.
Another alternative shaft 330 is illustrated in
Shaft 330 includes no guide portion extending upward from shaft 130, as shown in
Steps of another alternate opening operation is illustrated in
As noted previously, the exemplary latches described herein can have a lower protrusion as compared to conventional latches for enclosed spaces so as to reduce the area taken by the latches within those spaces. For example, when exemplary compression latches are used in connection with storage compartments, they can provide for a reduction of the degree of the protrusion of the latch into such compartments, thus decreasing or eliminating the effect of the latch on available storage space.
According to preferred aspects of this invention, this reduction of the degree of the protrusion of the latch is accomplished without compromising other performance benefits. For example, the invention makes it possible to reduce the degree of the protrusion of the latch as compared to conventional compression latches while at the same time maintaining at least one of or all of (1) the same pull-up or stroke of the latch's pawls as compared to conventional compression latches, (2) the same feel and smooth operation as compared to conventional compression latches, and (3) the same compressive force as compared to conventional compression latches.
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 application claims priority to Provisional Patent Application No. 62/192,264, entitled COMPRESSION LATCH HAVING A REDUCED PROTRUSION, filed on 14 Jul. 2015, the contents of which are incorporated herein by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2016/041873 | 7/12/2016 | WO | 00 |
Number | Date | Country | |
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62192264 | Jul 2015 | US |