The invention relates generally to latch assemblies for enclosures. More particularly, the invention relates to a latch assembly for securing a subassembly within an enclosure and for providing a handle to remove the subassembly from the enclosure.
Electronic equipment enclosures typically employ latch mechanisms to restrain removable electrical subassemblies installed therein. Various types of latch mechanisms currently exist for securing subassemblies within an enclosure. Some latch mechanisms are spring-loaded, that is, when a user disengages a spring-latch, the subassembly partially ejects from the enclosure; other latch mechanisms are not, and the subassembly scarcely moves, if at all, when the latch mechanism becomes undone. Often, the subassembly also has a handle upon which a user can pull in order to extract the disengaged subassembly from the enclosure. Aesthetics, cost, ease of installation, size, and EMI (electromagnetic interference) shielding are some important considerations in the design of a latch mechanism.
In one aspect, the invention features an apparatus having a handle with a grip portion and with a prong extending from the grip portion. The prong has an end and a groove formed near the end. The apparatus also has a leaf spring with a latching tab extending from a side thereof and a prong receptacle with a bore extending therethrough that closely receives the prong of the handle. The prong receptacle has a compressible region, wherein the compressible region is compressed within the groove of the prong to secure the handle to the leaf spring.
In another aspect, the invention features an apparatus, comprising a handle and a leaf spring. The handle has first and second prongs extending approximately parallel to each other from a finger-grip portion. The first prong has an end and a groove formed near the end. The leaf spring has an anchor portion for securing the leaf spring to a surface and a spring portion flexibly coupled at one end of the anchor portion. The spring portion has a first side with a latching tab extending therefrom and an opposite side with a first receptacle closely receiving the first prong of the handle and a second receptacle closely receiving the second prong of the handle. The first receptacle has a compressible region, wherein the compressible region is compressed within the groove of the first prong to secure the handle to the leaf spring.
In still another aspect, the invention features a method for attaching a latch-spring assembly to a subassembly. A handle and a leaf spring are positioned on opposite sides of a wall of the subassembly. A prong of the handle is inserted through an opening in the wall to enter a prong receptacle of the leaf spring. A compressible region of the prong receptacle is compressed into a groove formed in the prong of the handle. The leaf spring is attached to a sidewall of the subassembly such that a latching tab extending from a side of the leaf spring projects through an opening in the sidewall.
The above and further advantages of this invention may be better understood by referring to the following description in conjunction with the accompanying drawings, in which like numerals indicate like structural elements and features in various figures. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
The invention features a latch-spring assembly for securing a subassembly within an enclosure and a method for attaching the latch-spring assembly to the subassembly. Economical and easy to install, the latch-spring assembly is amenable to use with spring-loaded and non-spring-loaded subassemblies. The latch-spring assembly of the invention combines a latching mechanism, used to secure a subassembly to an enclosure, with a handle mechanism, used to disengage the latching mechanism and to pull the subassembly from the enclosure.
More specifically, the latch-spring assembly includes a wire form handle joined to a leaf spring. The leaf spring has a latching tab and attaches to an inside surface of a subassembly sidewall, where the leaf spring is generally hidden from view. The handle penetrates a front wall of the subassembly to join the leaf spring. The openings in the front wall through which the handle penetrates are sufficiently small for complying with EMI (electromagnetic interference) requirements.
To join the handle to the leaf spring, in one embodiment, the leaf spring has receptacles (cylindrical portions or barrel rolls) for receiving prongs of the handle. One of the prongs has a groove formed therein. One of the receptacles—the receptacle that is to receive the prong with the groove—has a notch cuts therein to produce a compressible region in that receptacle. The leaf spring has a stop tab for positioning the prong so that the compressible region stops over the groove when the prong that has penetrated the receptacle. Compressing this compressible region into the groove permanently fixes the handle to the leaf spring. The latch-spring assembly is fixed to the subassembly by fastening the leaf spring to a sidewall.
When the latch-spring assembly is attached to the sidewall, the latching tab extends through a corresponding opening in the sidewall. The latching tab engages in a corresponding latch-receiving mechanism on a sidewall of the enclosure within which the subassembly is inserted. The handle has an aesthetic, ergonomic, curved portion for laterally deflecting the leaf spring to disengage the latching tab from the latch-receiving mechanism and for pulling the subassembly out of the enclosure.
The second section 18 has a first cylindrical portion 24 at one edge thereof and a second cylindrical portion 26 at another edge thereof. Each cylindrical portion 24, 26 has a bore extending completely therethrough such that both ends of each cylindrical portion 24, 26 are open. The cylindrical portions 24, 26 are substantially parallel to each other. In one embodiment, the cylindrical portion 24 has a longer length than the cylindrical portion 26. Alternatively, the cylindrical portions 24, 26 can be equal in length or the cylindrical portion 26 can be longer than the cylindrical portion 24.
The first cylindrical portion 24 also has a notch 28 formed therein. The notch 28 partitions the first cylindrical portion 24 into two sections, a smaller section 24-1 and a larger section 24-2. The smaller section 24-1 defines a compressible region of the cylindrical portion 24.
The diameters of the bores of the cylindrical portions 24, 26 are sized to receive prongs 30-1, 30-2 (generally, 30) of the wire form handle 14. Projecting from an edge of the first section 16, substantially perpendicular to the plane of the first section 16, is a stop tab 32. The stop tab 32 is disposed adjacent to an open end of the first cylindrical portion 24, in a path of the prong 30-1 that extends through the first cylindrical portion 24. Although shown in
The second section 18 also has an opening 34 formed therein. Projecting from an edge of the opening 34—in
Formed from wire stock, e.g., of stainless steel or carbon steel, the handle 14 includes a curved portion 38 and the two substantially parallel, straight prongs 30 that extend from the curved portion 38. The size of the curved portion 38 is such that an individual can hook a finger therethrough, to pull on the handle 14 when drawing the subassembly out of an enclosure. The lengths of the prongs 30 are approximately equal to or longer than the lengths of the bores extending through the cylindrical portions 24, 26. Although
One of the prongs 30-1 has a groove 40 formed therein, that is, the groove 40 is a section of the prong with a smaller thickness or diameter than the diameter of the prong 30-1 on either side of the groove 40. The width of the groove 40 is wider than the width of the compressible region 24-1 of the first cylindrical portion 24. Although only prong 30-1 is shown to have a groove, either or both prongs 30-1, 30-2 can have a groove in the practice of the invention. In one embodiment, the length of the handle 14, measured from one end of the prong 30 to the tip of the curved portion 38, is approximately 2¾ inches.
At step 102, the leaf spring 12 and handle 14 are positioned on opposite sides of a front wall 64 of the subassembly 60, as shown in
At step 104, from the outside of the subassembly 60, the prongs 30 of the handle 14 are inserted through the openings 66 in the front wall 64, and into the open ends of the corresponding cylindrical portions 24, 26 of the leaf spring 12, until the probe 30-1 reaches the stop tab 32, which prevents further insertion of the prongs 30. As shown in
When the probe 30-1 reaches the stop tab 32, the compressible region 24-1 of the first cylindrical portion 24 encircles the groove 40 on the probe 30-1. Using a crimping tool 74, such as pliers, a technician crimps (step 106) the compressible region 24-1 into the groove 40. This permanently joins the handle 14 to the leaf spring 12, as shown in
At step 108, the technician attaches the leaf spring 12 by inserting fasteners 72 (e.g., rivets) into the openings 22 of the leaf spring to secure the first section 16 to the subassembly sidewall 62, as shown in
When a technician slides the subassembly 60 into an enclosure (not shown)—with the subassembly closely fitting within the enclosure—the sidewalls of the enclosure press against the sloped edges of the latching tabs 36 (one on each subassembly sidewall). Consequently, the leaf springs 12 bend laterally away from the enclosure sidewalls until the latching tabs 36 arrive at corresponding latch-receiving mechanisms on the enclosure sidewalls. Latch-receiving mechanisms can vary, for example, a depression in the enclosure sidewall or a raised or depressed vertical edge against which the straight back edge of the latching tab catches. Then the leaf springs 12 approximately return to their original (i.e., unbent) shape, with the latching tabs 36 becoming securely engaged with the latch-receiving mechanisms.
To remove the subassembly 60 from the enclosure, an individual deflects the handles 14 inwards (arrow 71) to deflect the leaf springs 12 away from the subassembly sidewalls, thus disengaging each latching tab 36 from its respective latch-receiving mechanism of the enclosure. When the latching tabs 36 become disengaged, the technician can then draw the subassembly 60 out of the enclosure by inserting his fingers through the curved portions 38 of the handles 14 and pulling (arrow 73).
The advantages of the latch-spring assembly include (1) an individual has a relatively large handle with which to grasp and pull out the subassembly 60 from an enclosure, (2) the size of the openings in the front wall 64 are large enough to receive the prongs 30, yet sufficiently small to satisfy EMI/RFI requirements, and (3) crimping is amenable to tight quarters.
While the invention has been shown and described with reference to specific preferred embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims. For example, the handle can be made of other materials other than wire stock (e.g., plastic).
Number | Name | Date | Kind |
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1943585 | Cummins et al. | Jan 1934 | A |
2227569 | Brooks | Jan 1941 | A |
2992034 | Wenk, Jr. | Jul 1961 | A |
4603453 | Yokoyama | Aug 1986 | A |
4827567 | Beach | May 1989 | A |
20010042281 | Forsline | Nov 2001 | A1 |
20030108300 | Walker et al. | Jun 2003 | A1 |
Number | Date | Country | |
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20060290146 A1 | Dec 2006 | US |