Switches having a single open circuit (off) position and two separate closed circuit (on) positions are useful in many power management scenarios. Some such scenarios require switching between two alternative power sources to provide electricity to a common load (e.g., switching between a municipal electricity grid and an auxiliary power source to provide electrical power to a given site). Other such scenarios require switching between two alternative loads and a single common power source (e.g.: switching between two separate sets of assembly line equipment and a single common power source at a manufacturing plant).
Some contemporary switch solutions providing a single open circuit (off) position and two alternative closed circuit (on) positions for industrial power management use two separate single throw switches, each having a single open circuit (off) position and a single closed circuit (on) position, configured to operate in opposite directions. Each such single throw switch requires a separate operating mechanism connected to a common handle through a linkage apparatus controlling which source or load is in use. Other contemporary switch solutions use two single throw switches in combination with a series of linkages and slider plates connected to a common actuator. Such contemporary switches require many component moving parts and are mechanically complex, and as a result are expensive to produce, repair, and maintain.
Some examples provide a switching mechanism for actuating a switch. The switching mechanism includes an actuator rotatable between an off position and an on position; and a timing disc assembly. The timing disc assembly includes an actuator disc, a bias disc, and a switch disc arranged in a stack such that the actuator disc, the bias disc, and the switch disc overlay each other. The actuator disc is rotatably connected to the actuator such that the actuator disc is configured to rotate with the actuator. The bias disc is connected to at least one biasing mechanism. The switch disc is connected to the switch. The actuator disc is configured to engage the bias disc such that the actuator disc is configured to rotate the bias disc to an overcenter position of the at least one biasing mechanism. The overcenter position of the at least one biasing mechanism is configured to rotate the bias disc such that engagement between the bias disc and the switch disc is configured to rotate the switch disc between a closed position and an open position of the switch.
Other examples provide a switch assembly. The switch assembly includes a switch having an open position and a closed position. The switch assembly also includes a switching mechanism operatively connected to the switch for actuating the switch between the open position and the closed position. The switching mechanism includes an actuator rotatable between an off position wherein the switch is in the open position and an on position wherein the switch is in the closed position. The switching mechanism also includes a timing disc assembly. The timing disc assembly includes an actuator disc, a bias disc, and a switch disc arranged in a stack such that the actuator disc, the bias disc, and the switch disc overlay each other. The actuator disc is rotatably connected to the actuator such that the actuator disc is configured to rotate with the actuator. The bias disc is connected to at least one biasing mechanism. The switch disc is connected to the switch. The actuator disc is configured to engage the bias disc such that the actuator disc is configured to rotate the bias disc to an overcenter position of the at least one biasing mechanism. The overcenter position of the at least one biasing mechanism is configured to rotate the bias disc such that engagement between the bias disc and the switch disc is configured to rotate the switch disc between the open position and the closed position of the switch.
Still other examples provide a switch assembly. The switch assembly includes a switch having a first set of electrical contacts and a second set of electrical contacts. The switch has an off position wherein the first set of electrical contacts is open and the second set of electrical contacts is open. The switch also has a first closed position wherein the first set of electrical contacts is closed and the second set of electrical contacts is open. The switch further has a second closed position wherein the first set of electrical contacts is open and the second set of electrical contacts is closed. The switch assembly further includes a switching mechanism operatively connected to the switch for actuating the switch between the open position and the first closed position and the second closed position. The switching mechanism includes an actuator and a timing disc assembly. The timing disc assembly includes an actuator disc and a switch disc arranged in a stack such that the actuator disc and the switch disc overlay each other. The actuator disc is rotatably connected to the actuator such that the actuator disc is configured to rotate with the actuator. The switch disc is connected to the switch. The actuator disc is configured to rotate the switch disc such that the switch disc moves the switch between the open position and the first closed position and the second closed position of the switch.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Corresponding reference characters indicate corresponding parts throughout the drawings.
Referring to the figures, examples of the disclosure provide a disc-based mechanism configured to operate a double throw switch with a single actuator. Examples of the disclosure operate without requiring any complex linkage apparatuses and/or slider plates connected to a common actuator. Depending on the configuration of the mechanism, a single actuator (e.g.: a single handle) controls which source or load is in use. The disclosure uses fewer components and is mechanically simpler than contemporary switches, and is therefore less expensive to produce, repair, and maintain.
The elements described herein operate in an unconventional manner to allow for operation of a double throw switch using a single mechanism. The disclosed mechanism improves the function of systems incorporating a double throw switch by, in a non-limiting example: (1) enabling a user to actuate the switch from the open position to either of the closed positions by manipulating a single actuator (as opposed to one actuator for each closed position); (2) in certain configurations, taking up considerably less physical space than contemporary switches using a combination of two single throw switches, linkages, and/or slider plates, thus increasing the available space for equipment utilizing the electricity delivered by the double throw switch, thereby potentially increasing efficiency of operations; and (3) extending the operational lifetime and time between routine maintenance and repairs by utilizing a mechanically simpler, more efficient, and more robust construction compared to contemporary switches. Examples of the disclosure are applicable to scenarios requiring fast, efficient, and safe switching of either (1) a single electrical current source between two electrical current loads; or (2) two electrical current sources between a single electrical current load. Thus, the disclosure can be configured based on the intended application to facilitate either an uninterrupted supply of power (via switching between a main and auxiliary power source) or the non-simultaneous use of a single power source by two electrical loads.
Referring now to
The switch 10 has an off position (also referred to as the open position 14) that is depicted in
As depicted in
As depicted in
The arrangement, configuration, manner of operation, and/or the like of the switch 10 is meant as exemplary only. The switch 10 can have other arrangements, configurations, manners of operation, and/or the like in other embodiments. For example, the exemplary embodiment of the first and second sets of electrical contacts 20 and 22, respectively, each include two contacts 220A, 220B, 222A, 222B, as well as two contact bridges 204A and two contact bridges 204B. But, each of the first and second sets of electrical contacts 20 and 22, respectively, can include any number of the electrical contacts 220A, 220B, 222A, 222B, any number of the contact bridges 204A, and any number of the contact bridges 204B. Optionally, corresponding contact bridges 204A and 204B are formed as a single, unitary structure, as is shown in the example of
Referring now to
Referring now to
In the exemplary embodiment, the switching mechanism 100 includes an actuator 102 and a timing disc assembly 108. The actuator 102 is moveable between an off position 104 (shown in
The rod 162 is received through the timing disc assembly 108 and is connected to both the connectors 214 and 212 to hold the timing disc assembly 108 together. The actuator linkage disc 122 is rotatably connected to the actuator 102 for rotation therewith. In the exemplary embodiment, the connector 214 includes a rectangular protrusion 218 that is received within a rectangular opening 224 of the actuator linkage disc 122 to interlock the connector 214 and the actuator linkage disc 122 such the actuator linkage disc 122 and the actuator 102 rotate together. But, any other arrangement, configuration, shape (e.g., of the opening 224 and/or the protrusion 218, etc.), and/or the like can be used to rotatably connect the actuator 102 to the actuator linkage disc 122.
The exemplary embodiment of the actuator disc 110 includes a flange 126 that is received between a pair of flanges 128A and 128B of the actuator linkage disc 122 to link the actuator disc 110 to the actuator linkage disc 122 for rotation therewith, as will be described below. The actuator disc 110 also includes flanges 130, 132, and 134. The bias disc 112 includes flanges 136 and 138, while the bias disc 114 includes flanges 140 and 142. The switch disc 116 includes flanges 144 and 146. Operation of the various flanges to drive rotation of the various discs will be described below. The flange 130 of the actuator disc 110 may referred to herein as a “first actuator flange”, while each of the flanges 132 and 134 of the actuator disc 110 may be referred to herein as a “second actuator flange”. Each of the flange 136 of the bias disc 112 and the flange 140 of the bias disc 114 may be referred to herein as a “first bias flange”. Each of the flange 138 of the bias disc 112 and the flange 140 of the bias disc 114 may be referred to herein as a “second bias flange”. Each of the flanges 144 and 146 of the switch disc 116 may be referred to herein as a “switch flange”.
Referring now to
In the exemplary embodiment, the actuator 102 includes a lever 150 having a handle 152 that is configured to be grasped by a user to move (i.e., rotate) the actuator 102 between the off position 104 and the on positions 106A and 106B. The actuator disc 110 is rotatably connected to the actuator 102 such that the actuator disc 110 is configured to rotate with the actuator 102. In the example shown herein, the actuator disc 110 is rotatably connected to the actuator 102 via the actuator linkage disc 122. For example, the actuator linkage disc 122 is rotatably connected to the actuator 102 for rotation therewith as described above. The flange 126 of the actuator disc 110 is received between the flanges 128A and 128B of the actuator linkage disc 122 such that the actuator disc 110 is interlocked with the actuator linkage disc 122. Accordingly, the actuator disc 110 is configured to rotate along with the actuator linkage disc 122 and thereby the actuator 102. But, any other arrangement, configuration, and/or the like can be used to rotatably connect the actuator disc 110 to the actuator 102 for rotation therewith in addition or alternatively to the actuator linkage disc 122. For example, the actuator disc 110 can be fixedly connected to, and/or interlocked with, the actuator 102 in other embodiments.
The bias disc 112 is operatively connected to the biasing mechanism 118, while the bias disc 114 is operatively connected to the biasing mechanism 120. The switch disc 116 is operatively connected to the switch 10 such that rotation of the switch disc 116 is configured to move the switch 10 between the open position 14 and the first closed position 12 of the switch 10 and is configured to move the switch 10 between the open position 14 and the second closed position 16 of the switch 10. In the exemplary embodiment, the connector 212 includes a rectangular protrusion 226 (shown in
As will be described in more detail below, the actuator disc 110 is configured to engage the bias disc 112 such that the actuator disc 110 is configured to rotate the bias disc 112 to overcenter positions 148 (shown in
As will also be described in more detail below, the actuator disc 110 is configured to engage the bias disc 114 such that the actuator disc 110 is configured to rotate the bias disc 114 to overcenter positions 154 (shown in
Continued rotation of the actuator 102 in the direction 156 advances the actuator disc 110, the bias disc 112, and the switch disc 116 in the direction 156 to the positions shown in
As shown in
The position of the switch disc 116 shown in
Movement of the actuator 102 from the first on position 106A to the off position 104 to thereby move the switch 10 from the first closed position 12 shown in
Continued rotation of the actuator 102 in the direction 166 advances the actuator disc 110, the bias disc 112, and the switch disc 116 in the direction 166 to the positions shown in
As shown in
The position of the switch disc 116 shown in
As described above,
Continued rotation of the actuator 102 in the direction 166 advances the actuator disc 110, the bias disc 114, and the switch disc 116 in the direction 166 to the positions shown in
As shown in
The position of the switch disc 116 shown in
Movement of the actuator 102 from the second on position 106B to the off position 104 to thereby move the switch 10 from the second closed position 16 shown in
Continued rotation of the actuator 102 in the direction 156 advances the actuator disc 110, the bias disc 114, and the switch disc 116 in the direction 156 to the positions shown in
As shown in
The position of the switch disc 116 shown in
The switching mechanism 100 optionally includes one or more interlock devices. In the exemplary embodiment, the switching mechanism 100 includes an interlock device 180 and an interlock device 182. The interlock device 180 is operatively connected to the actuator 102 such that the interlock device 180 is configured to prevent the actuator 102 from being rotated from the off position 104 to the on positions 106A (shown in
Although shown and described herein as including the lever 150 and handle 152 for manually operating the actuator 102 (i.e., manually moving the actuator 102 between the off position 104 and the on positions 106A and 106B), additionally or alternatively the switching mechanism 100 can be automatically moved between the off position 104 and the on positions 106A and 106B, for example using any suitable type of actuator, such as, but not limited to, an electro-mechanical device, an electric motor, a linear actuator (e.g., a ball screw, a lead screw, a rotary screw, another screw-type actuator, a hydraulic linear actuator, a pneumatic linear actuator, a solenoid, a servo, another type of linear actuator, etc.), a hydraulic actuator (e.g., a hydraulic pump system, etc.), a pneumatic actuator, a servo, and/or the like. In some examples, an automatically operated actuator 102 is controlled by another entity, such as, but not limited to, push-button controls, a computing device providing fully or partially automated control of the switching mechanism 100, remote triggers, radio controls, and/or the like. Some examples include a manually-operated actuator in addition to an automatically operated actuator for use when the automatic actuator malfunctions or is otherwise unavailable. Moreover, the manually operated actuator 102 is not limited to the lever 150 and handle 152 shown and described herein. Rather, other manually operated actuator configurations, arrangements, and/or the like can be provided in addition or alternatively to the lever 150 and/or handle 152.
Although shown herein as including two biasing mechanisms 118 and 120 for moving the switch 10 between the open position 14 and the first and second closed positions 12 and 16, respectively, the switching mechanism 100 can include any number of the biasing mechanisms that enables the switching mechanism to function as described and/or illustrated herein. For example, in some other embodiments the switching mechanism includes only one biasing mechanism for moving the switch 10 between the open position 14 and the first and second closed positions 12 and 16, respectively.
In the exemplary embodiment, each of the biasing mechanisms 118 and 120 is shown as including a helical spring. But, the biasing mechanisms 118 and 120 are not limited to including helical springs. Rather, each biasing mechanism 118 and 120 can include any other type of spring and/or other type of biasing mechanism that enables the switching mechanism 100 to function as described and/or illustrated herein, such as, but not limited to, a flat spring, a machined spring, a serpentine spring, a torsion spring, a tension spring, a constant spring, a variable spring, a variable stiffness spring, a leaf spring, a cantilever spring, a volute spring, a v-spring, and/or the like.
Unless explicitly stated otherwise herein, nothing in the disclosure herein is either intended to, or should be interpreted to, limit the number of poles usable with the disclosed switch mechanism, switch assembly, switch, etc.
At least a portion of the functionality of the various elements in
While the aspects of the disclosure have been described in terms of various examples with their associated operations, a person skilled in the art would appreciate that a combination of operations from any number of different examples is also within scope of the aspects of the disclosure.
The present disclosure is operable in a variety of environments for a variety of applications. For illustrative purposes only, and with no intent to limit the possible operating environments in which examples of the disclosure operate, the following exemplary operating environment is presented. The present disclosure is operable within a switch operating environment according to an embodiment as a functional bock diagram 800 in
The exemplary switch operating environment 800 comprises a main electrical power source 802 (e.g.: a feed from an electricity source configured to provide a constant, always-available source of electricity, including but not limited to: a municipal electrical grid, solar farm, wind farm, etc.) and an auxiliary electrical power source 804 (e.g.: a feed from a secondary and/or backup electricity source, including but not limited to one or more generators, configured for use when the main electrical power source 802 is unavailable). The switch operating environment 800 further comprises a powered facility 806. Examples of the powered facility 806 include but are not limited to: factories and manufacturing plants; hospitals; apartment buildings; houses; and buildings containing commercial office space.
The powered facility 806 comprises a double throw switch 808. In some examples, the double throw switch 808 is the switch assembly 200 containing the switch 10 and the switching mechanism 100 from
If the double throw switch 808 is in the open position, the double throw switch 808 will not conduct electricity from either the main electrical power source 802 or the auxiliary electrical power source 804 into the powered facility 806. If the double throw switch 808 is in the first closed position, the double throw switch 808 will conduct electricity from the main electrical power source 802 into the powered facility 806. If the double throw switch 808 is in the second closed position, the double throw switch 808 will conduct electricity from the auxiliary electrical power source 804 into the powered facility 806. Thus, the double throw switch 808 is usable not only to switch between two available power sources, but also, with minimal effort, to completely cut the supply of electricity to the powered facility 806 whenever necessary.
The powered facility 806 includes any number of electrically powered devices. In the exemplary embodiment, three electrically powered devices 812, 814, and 816 are provided. In embodiments wherein the powered facility 806 includes more than one electrically powered device 812, 814, and/or 816, the powered facility 806 optionally includes an electrical power distribution node 810. Each of the electrically powered devices 812, 814, and 816 can be any type of electrically powered device for any intended application, such as, but are not limited to, manufacturing equipment, medical equipment, commercial office equipment (e.g., computers and computer peripherals, telephones and other communications devices, etc.), utilities within the powered facility 806 (e.g., light fixtures; heating, ventilation, and air conditioning (“HVAC”) systems, electrically powered plumbing systems, etc.), and/or the like. Some examples of the electrical power distribution node 810 include but are not limited to, surge protectors, uninterrupted power supplies, and/or any other device configured to distribute electricity from a single circuit to multiple powered devices. In examples including the electrical power distribution node 810, any number of devices may be connected to the electrical power distribution node 810, such as the electrically powered device 812, the electrically powered device 814, and/or the electrically powered device 816.
In some examples of the switch operating environment 800, the double throw switch 808 is configured to draw electrical power from a single electrical power source and conduct electricity into one of two loads, as determined by the position of the double throw switch 808. In such examples, each load is either a single powered device or a group of powered devices. Such examples are an inversion of the example presented in
The examples of a double throw switch disclosed herein, including examples of switches, switching mechanisms, and switch assemblies, operate an electrical switch. Movement of an actuator transfers force to a timing disc assembly, which closes or opens either a first set of electrical contacts or a second set of electrical contacts depending on the direction of the movement of the switch and the original position of the switch. The actuator is also moveable into a position that leaves both the first set of electrical contacts and the second set of electrical contacts open, such that no electricity flows through either the first set of electrical contacts or the second set of electrical contacts. The disclosure allows a single switching mechanism to actuate the double throw switch from the off position to either the first closed circuit position or the second closed circuit position.
As described herein, the present disclosure provides systems for constructing and deploying a double throw switch comprising a single disc-based mechanism configured to operate a double throw switch with a single actuator. Examples of the disclosure do not require any complex linkage apparatuses and/or slider plates connected to a common actuator, use fewer components than contemporary switches, and are mechanically simpler than contemporary switches. Examples of the disclosure are therefore less expensive to produce, repair, and maintain.
While various spatial and directional terms, including but not limited to top, bottom, lower, mid, lateral, horizontal, vertical, front and the like may be used to describe the present disclosure, it is understood that such terms are merely used with respect to the orientations shown in the drawings. The orientations may be inverted, rotated, or otherwise changed, such that an upper portion is a lower portion, and vice versa, horizontal becomes vertical, and the like.
As used herein, a structure, limitation, or element that is “configured to” perform a task or operation is particularly structurally formed, constructed, or adapted in a manner corresponding to the task or operation. For purposes of clarity and the avoidance of doubt, an object that is merely capable of being modified to perform the task or operation is not “configured to” perform the task or operation as used herein.
The order of execution or performance of the operations in examples of the disclosure illustrated and described herein is not essential, unless otherwise specified. That is, the operations may be performed in any order, unless otherwise specified, and examples of the disclosure may include additional or fewer operations than those disclosed herein. For example, it is contemplated that executing or performing a particular operation before, contemporaneously with, or after another operation is within the scope of aspects of the disclosure.
When introducing elements of aspects of the disclosure or the examples thereof, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. The term “exemplary” is intended to mean “an example of” The phrase “one or more of the following: A, B, and C” means “at least one of A and/or at least one of B and/or at least one of C.” Further, the limitations of the following claims are not written in means-plus-function format and are not intended to be interpreted based on 35 U.S.C. § 112(f), unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
Having described aspects of the disclosure in detail, it will be apparent that modifications and variations are possible without departing from the scope of aspects of the disclosure as defined in the appended claims. As various changes could be made in the above constructions, products, and methods without departing from the scope of aspects of the disclosure, it is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
The following clauses describe further aspects:
Clause Set A:
A1. A switching mechanism for actuating a switch, the switching mechanism comprising:
A2. The switching mechanism of any preceding clause, wherein the actuator disc comprises a first actuator flange configured to engage a first bias flange of the bias disc that is configured to engage a switch flange of the switch disc to rotate the switch disc from the open position of the switch to the closed position of the switch, the actuator disc comprising a second actuator flange configured to engage a second bias flange of the bias disc that is configured to engage the switch flange to rotate the switch disc from the closed position to the open position of the switch.
A3. The switching mechanism of any preceding clause, wherein the bias disc is a first bias disc and the closed position of the switch is a first closed position, the timing disc assembly further comprising a second bias disc arranged within the stack and connected to the at least one biasing mechanism, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to the overcenter position of the at least one biasing mechanism, the overcenter position of the at least one biasing mechanism being configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and a second closed position of the switch.
A4. The switching mechanism of any preceding clause, wherein the bias disc is a first bias disc, the at least one biasing mechanism is a first biasing mechanism, and the closed position of the switch is a first closed position, the timing disc assembly further comprising a second bias disc arranged within the stack and connected to a second biasing mechanism, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to an overcenter position of the second biasing mechanism, the overcenter position of the second biasing mechanism being configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and a second closed position of the switch.
A5. The switching mechanism of any preceding clause, wherein the actuator disc is arranged within the stack between the bias disc and the switch disc.
A6. The switching mechanism of any preceding clause, further comprising at least one interlock device operatively connected to the actuator such that the at least one interlock device is configured to at least one of prevent the actuator from being rotated from the off position to the on position when a door of an enclosure is open or prevent the door from being opened when the actuator is in the on position.
A7. The switching mechanism of any preceding clause, wherein the actuator comprises a lever having a handle.
A8. The switching mechanism of any preceding clause, wherein the at least one biasing mechanism comprises a helical spring.
Clause Set B:
B1. A switch assembly comprising:
B2. The switch assembly of any preceding clause, wherein the actuator disc comprises a first actuator flange configured to engage a first bias flange of the bias disc that is configured to engage a switch flange of the switch disc to rotate the switch disc from the open position of the switch to the closed position of the switch, the actuator disc comprising a second actuator flange configured to engage a second bias flange of the bias disc that is configured to engage the switch flange to rotate the switch disc from the closed to the open position of the switch.
B3. The switch assembly of any preceding clause, wherein the bias disc is a first bias disc and the closed position of the switch is a first closed position, the timing disc assembly further comprising a second bias disc arranged within the stack and connected to the at least one biasing mechanism, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to an overcenter position of the at least one biasing mechanism, wherein the overcenter position of the at least one biasing mechanism is configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and a second closed position of the switch.
B4. The switch assembly of any preceding clause, wherein the bias disc is a first bias disc, the at least one biasing mechanism is a first biasing mechanism, and the closed position of the switch is a first closed position, the timing disc assembly further comprising a second bias disc arranged within the stack and connected to a second biasing mechanism, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to an overcenter position of the second biasing mechanism, the overcenter position of the second biasing mechanism being configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and a second closed position of the switch.
B5. The switch assembly of any preceding clause, wherein the actuator disc is arranged within the stack between the bias disc and the switch disc.
B6. The switch assembly of any preceding clause, wherein the switching mechanism comprises at least one interlock device operatively connected to the actuator such that the at least one interlock device is configured to at least one of prevent the actuator from being rotated from the off position to the on position when a door of an enclosure is open or prevent the door from being opened when the actuator is in the on position.
Clause Set C:
C1. A switch assembly comprising:
C2. The switch assembly of any preceding clause, wherein the timing disc assembly further comprises first and second bias discs arranged within the stack, the first and second bias discs being connected to at least one biasing mechanism, the actuator disc being configured to engage the first bias disc such that the actuator disc is configured to rotate the first bias disc to an overcenter position of the at least one biasing mechanism, the overcenter position of the at least one biasing mechanism being configured to rotate the first bias disc such that engagement between the first bias disc and the switch disc is configured to rotate the switch disc between the open position and the first closed position of the switch, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to an overcenter position of the at least one biasing mechanism, the overcenter position of the at least one biasing mechanism being configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and the second closed position of the switch.
C3. The switch assembly of any preceding clause, wherein the timing disc assembly further comprises first and second bias discs arranged within the stack, the first and second bias discs being connected to first and second biasing mechanisms, respectively, the actuator disc being configured to engage the first bias disc such that the actuator disc is configured to rotate the first bias disc to an overcenter position of the first biasing mechanism, the overcenter position of the first biasing mechanism being configured to rotate the first bias disc such that engagement between the first bias disc and the switch disc is configured to rotate the switch disc between the open position and the first closed position of the switch, the actuator disc being configured to engage the second bias disc such that the actuator disc is configured to rotate the second bias disc to an overcenter position of the second biasing mechanism, the overcenter position of the second biasing mechanism being configured to rotate the second bias disc such that engagement between the second bias disc and the switch disc is configured to rotate the switch disc between the open position and the second closed position of the switch.
C4. The switch assembly of any preceding clause, wherein the switching mechanism comprises at least one interlock device operatively connected to the actuator such that the at least one interlock device is configured to at least one of prevent the actuator from being rotated when a door of an enclosure is open or prevent the door from being opened when the switch is in the first closed position or the second closed position.
C5. The switch assembly of any preceding clause, wherein the actuator comprises at least one of a lever or an electro-mechanical device.
This Application claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 62/582,469, filed on Nov. 7, 2017, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
62582469 | Nov 2017 | US |