The disclosure relates to electrical component enclosures and in particular to latches for securing lids to electrical component enclosures.
Enclosures for housing electrical components such as printed circuit boards (PCBs), electronic modules and like electrical components are known. Enclosures are typically made of plastic or metal and are designed to house electrical components within a secured recess. The enclosures are adapted for installation in different indoor and outdoor environments to meet end application needs.
It is known for electrical component enclosures to have removable faceplates or lids. Lids may be secured in place to an enclosure through the use of various kinds of retention latches.
It is known to actuate latch components through the use of elongate tools having blade, such as a screwdriver to allow lid removal.
The process of using a tool to actuate latch components is problematic. To actuate latch components, the tool blade must be properly located to engage and exert forces onto certain latch elements. Properly locating a tool blade to actuate small latch components can be difficult and time-consuming.
As latch elements may be located within an enclosure recess or other protective structure to prevent inadvertent latch actuation, visual confirmation of component engagement and actuation by a tool blade is difficult or not possible in the field. This can result in poor location of the tool blade.
When a disengagement force is applied to the tool, poor location of the tool blade can result in failed actuation of latch elements, undesired placement of the tool blade away from latch elements and potential damage to the enclosure or the components held therein.
Once the actuation of the latch elements is achieved, a user must use a free hand to remove the lid from the enclosure body while continuing to apply the disengagement force on latch elements though the tool blade. The need to use two hands simultaneously to achieve lid removal complicates the procedure and further increases the risk for blade dislocation.
Thus, it is desirable to provide an electrical component enclosure that allows for improved latch actuation. The enclosure should allow user actuation through use of a tool blade to overcome the challenges discussed above.
Disclosed is an electrical component enclosure assembly that provides improved latch actuation and lid removal through the use of hand tools having a flat blade, such as a screwdriver blade.
The disclosed enclosure includes elements to properly locate a tool blade proximate latch elements and facilitate the application of force by the tool blade to actuate latch elements and disengage the enclosure lid in one motion. The enclosure allows for simplified disengagement the lid from the enclosure.
The disclosed enclosure also provides the user with physical feedback to inform the user of proper latch actuation during the lid removal procedure.
Other objects and features will become apparent as the description proceeds, especially when taken in conjunction with the accompanying drawing sheets.
As shown in the figures, enclosure body 12 is generally rectangular in shape and is made up of five body walls: top wall 18, bottom wall 20, side walls 22, 24, and rear wall 26. Enclosure mouth opening 28 leads into enclosure internal cavity 30. The surrounding body walls define cavity 30 which has a generally rectangular shape, having a major axis 32 extending from the enclosure mouth 28 to rear wall 26 and a minor axis 34 extending between side walls 22, 24. Minor axis 34 extends generally parallel to enclosure mouth opening 28.
Two enclosure assembly feet 36 extend from the bottom of body 12 proximate enclosure body side walls 22, 24 and enclosure body bottom wall 20. Each foot 36 is generally rectangular in shape and may have foot apertures 38 extending through the foot. As illustrated in
Enclosure internal cavity 30 may include mounting elements to facilitate the secure installation of a printed circuit board, electronic modules and like electrical components therein. Enclosure body side walls 22, 24 having side wall interior surfaces 40, 42 may each have a PCB holder slot 44. Each holder slot 44 faces the holder slot 44 on an opposed side wall interior surface. Slots 44 are sized to accept a printed circuit board or like generally flat electrical component element.
In other embodiments, enclosure internal cavity 30 may have other mounting elements to facilitate the installation of an electrical component therein. An electrical component may be mounted to an enclosure body interior wall surface by conventional a fastener, adhesives or the like.
Enclosure lid or faceplate 14 has a generally flat, rectangular shaped body 50. Body 50 has a front face 52 and a rear face 54. Body 50 includes faceplate top and bottom portions 56, 58 and faceplate side portions 60, 62.
The rear face 54 of lid or faceplate 14 may include a circumferential mounting flange 64 extending away from face 54. Mounting flange 64 is made of a flange wall 66 having a generally uniform thickness and being generally rectangular in shape, extending circumferentially proximate body 50 portions 56, 58, 60 and 62. Mounting flange 64 is adapted to fit within the interior of enclosure mouth 28 when lid or faceplate 14 engages enclosure body 12 at the closure of assembly 10.
Mounting flange 64 may include a circumferential gasket 68 located at the exterior of mounting flange 64. Gasket 68 may be made of silicone, rubber or a like elastomer to provide an improved fit between mounting flange 64 and the interior of enclosure mouth 28 as well as protection from moisture seepage, environmental contamination and the like into cavity 30 at the closure of assembly 10.
The rear face 54 of lid or faceplate 14 may also include a pair of PCB holder slots 70 located between opposed cover side portions 60, 62 and extending inwardly from flange wall 66 as shown in
In embodiments, a printed circuit board 80 or like electrical component including generally flat elements may be mounted to assembly 10. This may be accomplished by insertion of a board 80 having opposed side edges 82 into cavity 30 so that edges 82 engage PCB holder slots 38 and/or PCB holder slots 70. In embodiments, a printed circuit board 80 may include one or more mounting apertures 84 located proximate edges 82 and aligned with flange mounting aperture 74 during board installation. A faster located through aligned apertures 74 and 84 may be used to secure a printed circuit board 80 to faceplate 14.
Electrical component enclosure assembly 10 includes a pair of enclosure faceplate actuation assemblies 100, each assembly located proximate the enclosure mouth 28 a side wall 22, 24 respectively.
Each actuation assembly 100 is formed by a retention latch assembly 102 located on enclosure body 12 and a latch engagement assembly 104 located on faceplate 14.
Each retention latch assembly 102 is located on an enclosure body side wall 22, 24 and proximate enclosure mouth 28.
Each retention latch assembly 102 includes a latch arm 105 extending from latch base 106 to a latch hook 108. Latch base 106 is joined to an enclosure body side wall 22, 24 and may include a latch security aperture 107 extending from the top of the base proximate top wall 18 to the bottom of the base proximate bottom wall 20.
Latch arm 105 is flexible and to allow deflection during assembly use as described below.
Latch hook 108 includes latch head 110 having camming surface 112 and hook retention surface 114.
Each latch engagement assembly 104 is located on a faceplate portion 60, 62 and extends away from front face 52 proximate mounting flange 64. See
Each latch engagement assembly 104 includes a generally C-shaped latch engagement assembly wall 120 having a top wall 122, a side wall 124 and a bottom wall 126 as shown in
Tool positioning aperture 128 includes a circumferential mouth having a chamfered surface 130 located adjacent the outer surface of top wall 122.
The outer surface of top wall 122 may include a locating indicia 131 proximate tool positioning aperture 128. In the figures, locating indicia 131 is shown as an arrow symbol pointed toward aperture 128, but other indicia symbols may also be used. The use of an arrow symbol may indicate the direction of rotation for a tool inserted into tool positioning aperture 128 to actuate the assembly latch in use of the assembly as described below.
As tool blade 202 is fully inserted into tool-location cavity 142, tool 200 is rotated from a vertical position as shown in
Top and bottom walls 122, 126 include aligned engagement assembly security apertures 132.
Latch engagement assembly wall 120 defines a latch engagement assembly cavity 134 within each latch engagement assembly 104. Cavity 134 is generally defined by walls 122, 124, 126 and faceplate mounting flange 64. See
Within cavity 134, assembly side wall 124 includes retention element 136, having camming surface 138 and retention surface 140.
Cavity 134 also includes tool-location cavity 142 defined generally by retention surface 140, side wall 124, and the rear face 54 of faceplate 14.
Tool-location cavity 142 is located under and is generally continuous with tool positioning aperture 128.
Tool-location cavity 142 includes ramp element 144 having a ramp surface 146. Ramp surface 146 generally faces away from wall 124 and toward flange 64. Ramp surface 146 tapers outwardly as it extends from tool positioning aperture 128 to ramp element base 148. See
As shown in
When enclosure faceplate 14 is mounted to enclosure body 12 in assembly 10, aperture 128 minor axis 154 is off-set from the minor axis 34 of cavity 30 by an angle A. Angle A may be approximately 25 degrees. In embodiments, angle A may range between 20 degrees and 30 degrees.
In assembly embodiments, aperture 128 major axis 152 is off-set from the major axis 32 of cavity 30 to the same degree as latch hook 108 camming surface 112 is off-set from the major axis 32 of cavity 30. This configuration allows reliable contact between a tool blade inserted into tool positioning aperture 128 and camming surface 112 as disclosed below.
Rectangular cross section 150 of tool positioning aperture 128 allows is sized to allow the insertion of tools having a flat blade, such as a flat screwdriver blade. In assembly embodiments, the length of the major axis 32 may be approximately 3.6 millimeters and the length of minor axis 34 may be approximately 2.6 millimeters to allow insertion of a correspondingly sized flat screwdriver blade.
Use of electrical component enclosure assembly 10 will now be described.
In the secured position retention latch assembly latch security aperture 107 and latch engagement assembly security apertures 132 are aligned to allow placement of a security retention band, zip-tie of like security retention element to secure assembly 10 in the secured position, prevent tampering with assembly 10 and/or provide an indication in case assembly tampering occurs.
Hand tool 200 is shown in the figures as a flathead screwdriver having a tool blade or tool end 202. Use of other types of hand tools with assembly 10 is also contemplated, such tools having an elongate shaft terminating at a shaft end that is generally uniform with the shaft including Phillips head screwdrivers, awls and like tools, so long as the shaft end properly fits within tool positioning aperture 128.
Assembly locating indicia 131 directs a user to insert a tool blade 202 into tool positioning aperture 128.
Additionally as tool blade 202 is fully inserted into tool-location cavity 142, tool 200 is rotated from a vertical position as shown in
Through the latch disengagement procedure, tool blade 202 exerts a displacement force 210 having force component vectors 212 and 213 as shown in
Tool positioning aperture's 128 rectangular cross section 150 may be located so that major axis 152 is generally parallel to latch hook 108 camming surface 112. This allows a blade 202 inserted into aperture 128 and tool-location cavity 142 to establish reliable contact with latch head and camming surface 112. Additionally, rectangular cross section 150 is sized to prevent the mis-positioning blade 202 so that the blade properly actuates latch arm 105. This locating of tool positioning aperture's 128 also assures that tool blade 202 provides a displacement force 210 having force component vectors 212 and 213 as described herein.
The procedure is repeated for both actuation assemblies 100 to allow for removal of faceplate 14 from body 12.
At appropriate application of a displacement force 210, faceplate 14 is partially forced off of body 12 as latch head camming surface 112 passes along camming surface 138. This motion provides a user with physical feedback confirming proper latch actuation for faceplate removal.
While the present disclosure illustrates an electrical component enclosure 10 having a pair of actuation assemblies 100 located on opposed sides enclosure 12 to secure a faceplate thereto, alternate embodiments are contemplated. Alternate embodiments may include an enclosure having a single lid retention assembly 100 as well as enclosures having more than two actuation assemblies 100.
Also, while the present disclosure illustrates an actuation assembly 100 having a retention latch assembly 102 located on enclosure body 12 and a latch engagement assembly 104 located on faceplate 14, alternate embodiments are contemplated. Alternate embodiments may include an assembly having a actuation assembly 100 having a retention latch assembly 102 located on faceplace 14 and a latch engagement assembly 104 located on body 12.
While this disclosure discloses and describes various embodiments, it is understood that this is capable of modification and that the disclosure is not limited to the precise details set forth, but includes such changes and alterations as fall within the purview of the following claims.
Number | Name | Date | Kind |
---|---|---|---|
5551589 | Nakamura | Sep 1996 | A |
5577779 | Dangel | Nov 1996 | A |
D377339 | Beruscha et al. | Jan 1997 | S |
6486399 | Armstrong et al. | Nov 2002 | B1 |
6550170 | Cooper et al. | Apr 2003 | B1 |
6969034 | Ware et al. | Nov 2005 | B2 |
6988697 | Ware et al. | Jan 2006 | B2 |
7059572 | Ware et al. | Jun 2006 | B2 |
7413479 | Volpone | Aug 2008 | B1 |
7417868 | Morisada | Aug 2008 | B2 |
8648264 | Masumoto | Feb 2014 | B2 |
9113561 | Kominami et al. | Aug 2015 | B2 |
9161465 | Chen et al. | Oct 2015 | B2 |
9214793 | Shiraki | Dec 2015 | B2 |
9967993 | Walker et al. | May 2018 | B1 |
9985422 | Jett et al. | May 2018 | B2 |
D827575 | Oyster | Sep 2018 | S |
10129993 | Tollefsbol et al. | Nov 2018 | B2 |
10386013 | Walker et al. | Aug 2019 | B2 |
20080239632 | Wayman | Oct 2008 | A1 |
20090289158 | Nelson et al. | Nov 2009 | A1 |
20120001041 | Yang et al. | Jan 2012 | A1 |
20130026160 | Hu | Jan 2013 | A1 |
20160007488 | Neustadt | Jan 2016 | A1 |
Number | Date | Country |
---|---|---|
19642517 | Apr 1998 | DE |
2018224484 | Dec 2018 | WO |
2019192925 | Oct 2019 | WO |
Number | Date | Country | |
---|---|---|---|
20220087042 A1 | Mar 2022 | US |