NOT APPLICABLE
NOT APPLICABLE
The invention relates to switch assemblies, and in particular relates to a reliable contact block with a double break spanner.
Electrical switches, such as pushbuttons or rotary switches, and the like, used for the control of industrial equipment, are typically mounted onto a front panel of a cabinet so that the manipulated portion of the switch (termed the “pushbutton operator”) projects out from and is accessible at the front of the cabinet.
For a pushbutton switch, a hole of sufficient diameter may be punched in the cabinet to accommodate the threaded portion of the operator The threaded portion is inserted through the hole, and secured to the panel with a threaded retaining nut. The panel is thus sandwiched between the operator and the retaining nut.
A latch assembly is mounted on the end of the operator protruding inside the panel and a contact block or a plurality of contact blocks are mounted onto the other side of the latch assembly. The contact blocks are electrically connected to the circuit or circuits that the switch is to control.
Contact blocks typically include housings that contain normally open and/or normally closed contacts. A normally open contact may be used, for example, when a user wishes to activate a specified function by actuating the operator, thereby closing the normally open contact. When the operator switch is deactivated, a plunger returns to its normal position, thereby opening the normally open contact and terminating the controlled function.
A normally closed contact may be used when a user wishes to stop an ongoing function. One common example of a normally closed contact is an Emergency Stop (E-Stop) function which is activated when the user wishes to immediately terminate the controlled function due, e.g., to a malfunction in the process or the development of a situation that may cause damage to the product line or the operating equipment. In this situation, when the switch operator is actuated, the normally closed contact opens and remains open until the operator is returned to its normal state, thereby closing the normally closed contact and resuming the controlled function.
Referring to
Referring now to
What is therefore needed is a switch usable in a contact block that provides redundancy without compromising the structural integrity of the switch components during use.
In one aspect, a switch is provided that is of the type that may be installed in a contact block engaging a pushbutton operator via a latch assembly. The switch includes a contact defining a first and second end. The first end is connected to an external device controlled by the switch. A first and second nub extends outwardly from the second end. A laterally extending conductive spanner has a body connected to an outer end that is aligned with the first and second nubs of each second end, respectively. A circuit is formed when the spanner is electrically connected to the second end. The outer ends of the spanner are wider than the central portion so as to render the spanner torsionally compliant.
These and other aspects of the invention are not intended to define the scope of the invention for which purpose claims are provided. In the following description, reference is made to the accompanying drawings, which form a part hereof, and in which there is shown by way of illustration and not limitation a preferred embodiment of the invention. Such embodiment does not define the scope of the invention and reference must therefore be made to the claims for this purpose.
Preferred exemplary embodiments of the invention are illustrated in the accompanying drawings in which like reference numerals correspond to like elements throughout, and in which:
Referring to
Switch operator 54 includes a pushbutton 66 located at a head 68 at one end of cylindrical shaft 62. The pushbutton 66 is attached to a stem 70 that extends axially through the shaft 62 to communicate the action of the pushbutton 66 to a plunger 72 in the contact block 52. A sheet panel 74, preferably made of sheet metal, has a hold (not shown) that receives the shaft 62, such that pushbutton 66 extends from the outer surface of panel 74, and the contact block 52 extends inwardly from the inner surface of a panel 74. External threads 76 are formed on the portion of the shaft 62 passing through the hole in panel 74. The head 68, remaining on the outside of the panel 74 when the shaft 62 is inserted into the hole, is drawn against the panel by a retaining nut 78, placed over the shaft inside of the panel, and tightened on the threads 76. The panel is thus sandwiched between the nut 78 and an inner face of the head 68.
While pushbutton 66 and latch assembly 50 have been described, it should be noted that any suitable apparatus for connecting the switch operator 54 to a contact block 52 may be used such that actuation of the switch operator in turn actuates the contact block plunger.
Housing 56 of contact block 52 retains a switch assembly 55 that is in a normally open position. Housing 56 includes opposing front and rear walls 80 that are connected at their outer ends to side walls 82. Walls 80 and 82 are connected at their lower ends to a base 83, and are connected at their upper ends to an upper wall 85. A pair of contact assemblies 84 is formed at each lateral end of walls 80 and are separated by a centrally disposed axially extending column 86 that comprises a void disposed between walls 80 of adjacent contact assemblies 84.
It should be appreciated that the term “axially” is used herein synonymously with “vertical” and defines a direction between contact block 52 and pushbutton 66. The term “laterally” is used herein to define a direction extending perpendicular to side walls 82. The term “transverse” is used herein to define a direction extending perpendicular to front and rear walls 80. These directional terms are used for the purposes of clarity and convenience, however the components of the present invention are not to be construed as limited to these directions.
Each contact assembly 84 includes a lower retaining wall 88 that extends upwardly from base 83 parallel to side walls 82 at a distance inwardly of side walls 82. The upper end 90 of each retaining wall 88 provides a seat for the inner end 92 of an electrically conducting plate 93. A pair of corresponding lower guide walls 94 extends upwardly from base 83 a distance less than lower retaining wall 88, and is connected to the adjacent lower retaining wall 88 via a crossbar 96 to ensure structural integrity.
A pair of upper retaining walls 98 extends downwardly from upper wall 85 parallel to side walls 82 at a distance inwardly of side walls 82. The lower end of each upper retaining wall 98 is connected to a mounting wall 100 that extends laterally outwardly to the corresponding side wall 82. A pair of corresponding upper guide walls 102 extends downwardly from upper wall 85 a distance less than upper retaining walls 98, and is connected to the adjacent upper retaining wall 98 via a crossbar 104 to ensure structural integrity.
An angled wall 107 is connected to the interface 106 of mounting wall 100 and one of the side walls 82. Wall 107 extends generally upwardly and then generally inwardly and is connected to the upper end of corresponding upper retaining wall 98 to provide structural support for release tab 64. In particular, the interface 106 provides a hinge that enables the corresponding side wall 82 to flex outwardly in when release tab 64 is engaged.
Each mounting wall 100 defines an aperture 108 extending through the wall 100 in a direction perpendicular to the wall 100. Each electrically conducting plate 93 defines an outer end 110 that extends along the bottom surface of mounting wall 100. A cylindrical flange 112 extends generally upwardly from outer end 110 and into aperture 108. Flange 112 defines an internally threaded bore. Flange 112 receives a screw 114 having a middle threaded portion 116, a lower threaded portion 120 proximal the screw tip, and an upper threaded portion 118 proximal the screw head.
A V-shaped conducting electrical connector 122 includes first and second walls 124 joined at an apex whose concave surface faces plate 93. Apex 124 receives the upper unthreaded portion 118 of screw 114, which has a smaller diameter than the outer diameter of threads 116. Flange 112 receives the threaded portion 116, such that the lower unthreaded portion 120 extends beyond flange 112. Screw 114 may be rotated clockwise to tighten connector 122 against plate 93, or counterclockwise to translate connector 122 away from plate 93. An electrical lead is placed between each connector 122 and plate 93 prior to tightening the respective connector against the plate. Connector 122 is sized too large to fit through a gap 125 disposed between the lower end of side wall 82 and lower retaining wall 88. Unthreaded portions 120 and 118 are spaced apart a sufficient distance such that, when screw 114 is rotated counterclockwise until threads 116 become disengaged from flange 112, connector 122 is disposed above gap 125. The mechanical interference between threads 116 and connector 122 coupled with the interference between connector and gap 125 prevents the screw 114 from being completely removed from contact block 52.
Column 86 is occupied by a housing 130 that carries an electrically conducting laterally extending spanner 126 that, in combination with inner ends 92 of plates 93, provides a normally open switch 133. Specifically, referring also to
Plunger 72 extends upwardly from the upper wall 132 of housing 130. A pair of opposing side walls 134 have corresponding proximal ends 136 that are connected to the transverse outer edges 138 of wall 132 (See also FIG. 10). Side walls 134 extend downwardly from upper wall 132 and terminate at distal ends 140. The distal ends 140 retain a plug 142, which may be snap-fit between walls 134. Distal ends 140 of walls 134 extend downwardly a slight distance past plug 142, and are separated from each other a distance slightly greater than the transverse thickness of base 83 to enable contact blocks 52 to be vertically stacked, as will be described in more detail below.
The upper surface 144 of plug 142 provides a seat for spanner 126. The lateral outer ends of each wall 134 are flared inwardly towards the opposing wall 134 to define flanges 143. Flanges 143 provide a guide for an upper spring 145 that is disposed in housing 130 such that the upper end 146 of spring 145 rests against the lower surface of upper wall 132, and the lower end 148 of spring 145 biases spanner 126 against the upper surface 144 of plug 142. A bore 149 extends axially upwardly through the lower surface 146 of plug 142. Bore 149 extends towards, but not all the way to, the upper surface 144. Bore 149 is sized to receive the upper end 150 of a lower spring 152 whose lower end 154 is in contact with base 83 of contact block housing 56. Lower spring 152 thus biases housing 130 upwardly such that plunger 72 engages the lower end of stem 70 and spanner 126 is disengaged from plates 93 when contact block 52 and operator 54 are initially installed in latch 50.
Referring now also to
Spanner 126, which is carried by the housing 130, is thus also biased downwardly until outer ends 127 engage the inner ends 92 of plates 93. Advantageously, upper spring 145 provides compliance such that housing 130 may continue to be biased downwardly against the force of upper spring 145, which compresses after spanner 126 engages plates 93. Spring 145 thus provides a force that biases spanner 126 against plates 93. The biasing force of spring 145 increases as housing 126 is increasingly depressed. The downward movement of housing 126 is limited by the stroke length of pushbutton 66, or by interference between the lower surface 146 of plug 142 and base 83.
Referring now to
Beam 156 has a width (transverse thickness) at locations 162 between protrusions 158 and outer ends 127 that is less than the width of ends 127. Ends 127 are thus T-shaped with respect to the beam sections 162. Ends 127 extend further transversely outwardly than protrusions 158 such that the entire beam 156 has a reduced width with respect to outer ends 127. The beam structure, along with the fact that beam 156 is made of a flexible material, combine to enable beam 156 to provide torsional compliance during operation.
Specifically, referring also to
In accordance with the present invention, however, the portions 162 of spanner 126 have reduced transverse thicknesses relative to the corresponding lateral outer ends 127. Furthermore, spanner 126 is made of a compliant material and has a reduced axial thickness (within the range of 25 mm). Accordingly, when one transverse outer end 135 is raised with respect to corresponding nub 99, the force of upper spring 145 acting on the middle portion 160 of spanner 126 is translated to the other transverse outer end 123 so as to bias end 123 against the corresponding nub 101. Redundant contacts are thus established at each lateral outer end 127 between transverse outer ends 135 and 123, and nubs 99 and 101, respectively. Nonconductive mass 161 furthermore does not affect the ability of the opposite outer end 127 of spanner 126 to contact corresponding nubs 99 and 101.
When switch 133 is again opened, one of the transverse outer ends 123 or 135 will, if only for a minute period of time, become disengaged from the corresponding nub prior to the other transverse outer end. For instance, outer end 135 may become disengaged from nub 99 prior to outer end 123 becoming disengaged from nub 101. An arc may thus form at the interface between the remaining end 123 and nub 101. Transverse outer ends 135 and 123 are not bifurcated, however, meaning that lateral outer end 127 is a solid member that includes both transverse outer ends. Accordingly, even though an arc may be produced at outer end 123 when the switch 133 is opened, the increased thermal mass of lateral outer end 127 enables spanner 126 to absorb the arc while maintaining its structural integrity.
The redundancy of bifurcation in conventional spanners is thus replaced by the redundancy of torsional compliance in accordance with the preferred embodiment of the present invention. The lack of bifurcation allows the total mass of the spanner to participate in the opening and closing of the circuit hence reducing the detrimental thermal effects of the arc. This increases contact life and prevents contact welding. Thus, spanner 126 affords the same contact reliability of a bifurcated spanner while increasing structural reliability in the face of arcing during use.
As discussed above, sections 162 have a reduced width compared to the width of outer ends 127, and further have a reduced width compared to the width of middle portion 160. The reduced width of sections 162 is achieved by forming a corresponding pair of notches 163 between outer ends 127 and middle portion 160. Advantageously, notches 163 ensure that heat that accumulates at outer ends 127 thus has a reduced path of conductivity via sections 162. The middle portion 160 thus does not become heated as rapidly as conventional spanners, thereby further reducing potentially damaging thermal effects on nearby plastic parts.
Referring now to
Referring now to
The invention has been described in connection with what are presently considered to be the most practical and preferred embodiments. However, the present invention has been presented by way of illustration and is not intended to be limited to the disclosed embodiments. Accordingly, those skilled in the art will realize that the invention is intended to encompass all modifications and alternative arrangements included within the spirit and scope of the invention, as set forth by the appended claims.
Number | Name | Date | Kind |
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4249057 | Schlegel et al. | Feb 1981 | A |
5045655 | Ludwig et al. | Sep 1991 | A |
5744766 | Sambar et al. | Apr 1998 | A |
6198058 | Graninger et al. | Mar 2001 | B1 |
6376785 | Graninger | Apr 2002 | B1 |
Number | Date | Country |
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1 443 954 | Jul 1965 | FR |
1 080 279 | Aug 1967 | GB |
1 204 398 | Sep 1970 | GB |
Number | Date | Country | |
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20040245083 A1 | Dec 2004 | US |