This disclosure is related to the field of switches and particularly multi-position switches that can include multiple redundancy at each position.
Switches, and particularly electrical switches, are currently ubiquitous in daily human life. Switches come in all shapes and sizes and from the simple to the complex. While they are near ubiquitous, different switches need to be built to handle particular tasks. A switch, as we tend to think of it, actually includes two “switching” elements. The first of these is the underlying electrical or circuit switch which is, in many respects, the true switch. This is typically very small and is the object that physically connects and disconnects the electrical or circuit path switched by the switch. It, thus, acts to open or close the circuit which carries out the functionality the switch is related to.
The second component of the switch is the interaction component or switch head. This is typically much larger and is designed to be manipulated by a human (or other) user. The head of the switch is what many people think of as a “switch” but technically is nothing other than a specialized lever, toggle, or other piece which is configured to allow for convenient manipulation by human hands, which are typically quite large relative to the underlying electrical circuit switch, to control the action of switching the circuit.
It is in the creation of the interface between the switch head and the circuit switch where the differences in switches typically lie. As indicated, human hands (or any other body part we would want to activate a switch) are relatively large compared to electrical components which can be purposefully highly miniaturized. However, they are also highly manipulable within 3-Dimensional space with a very wide range of motion. Thus, macro scale switches are really devices to translate specific human motion acting on the switch head into an expected electrical opening or closing circuit action which circuit action causes an electrical device to behave as the human intended by their act of manipulating the head in the particular fashion they did. Thus, items we think of as switches, such as a light switch, act to take a human motion (e.g. the pushing of a toggle head up or down or the depression of a particular part of a lever head) and translate that into circuit switching in the light circuit to create the desired action of turning the light on or off.
A lot of the purpose of a switch unit is, thus, to give a human user a clear way to manipulate the operation of the underlying circuit so it does what it is intended to do when the user instructs it to do so. The need for accurate translation of human movement into actual circuit switching can be convenient or essential depending on the purpose of the switch. As electrical objects pervade human existence currently, and we trust many of them with both our and others' lives, it is, thus, highly desirable to have switches that consistently and repeatedly switch circuits when the same human actions are performed.
One place where highly accurate switching is necessary is in the operation of complex machines, particularly when the operation of those machines is directly related to the maintenance or loss of human life. While there are large numbers of such applications, one is in the operation transportation machines such as cars, trucks, boats, and aircraft.
Powered flight can easily be considered one of humankind's greatest accomplishments. The modern aircraft is an amazing piece of engineering and the skill requirements of a human pilot to keep it aloft are also impressive. Operation in three-dimensional space presents aircraft with a number of concerns that ground based vehicles simply do not have and also tends to require a human operator to need to make many more choices to keep the operation of the aircraft safe. In the first instance, humans, whether as operators or passengers in an aircraft, are not native to the skies. Aircraft have to deal with the fact that they are operating in an environment which, typically, does not allow for a safe stop to disembark human passengers or crew. A ground-based vehicle can typically be simply stopped if there are concerns in its operation, passengers and operators can disembark, and the vehicle can be safely inspected and repaired. Thus, in most cases, ground-based vehicles major concern with failure of operation is safely coming to a stop and not in being able to get where they are going.
In an aircraft, there is typically no way to safely stop in midair. Instead, should an aircraft discover a midair concern, the aircraft still needs to have a place to land and safe landing typically requires sufficient aircraft operability, sufficient landing space, and sufficient pilot control for the aircraft to return to earth in a controlled fashion and without hitting anything. An aircraft in midair is effectively only safe so long as it continues to operate correctly and safe midair operation, at least currently, is dependent on a human pilot's skills in piloting the aircraft being correctly translated by switches into aircraft actions.
In order to keep aircraft operating correctly, its electrical systems are paramount as they control virtually everything and act to communicate a pilot's requested actions into aircraft actions. Because of this, many of an aircraft's electrical systems require redundancy and this is true even down to items as simple as switches. A large number of aircraft systems are operated by switches of some form from simple toggle switches for turning components on and off to the complicated motions of a control stick which is translated by many switches into the direction that the pilot wishes to go. In order to improve safety within aircraft, many of these switches operate on double, triple, or even increased redundant circuit switches. This redundancy helps make sure that the action taken by the pilot with the macro switch they are interacting with is carried out by the underlying circuit switch since failure of a single circuit switch in the system will generally not cause the intent of the pilot to not be translated into switching within the circuit.
In addition to the need for redundancy in switches in aircraft for the purposes of safety, switches, particularly in aircraft, are often required to control many different things because of the sheer number of items that a pilot needs to control. When flying an aircraft, and particularly a rotorcraft, the pilot will often have both hands and both feet engaged with controls at all times. Thus, the need to activate additional controls that are needed during piloting typically requires that switches be located in easy reach and ideally on other controls.
To provide easy access to auxiliary controls while piloting, many of these controls (which can include everything from lighting controls, to controls over payloads, to controls for displays, to the operation of weapon systems on military aircraft) are located on the control sticks, grips, or wheels of aircraft that are held by the pilot while piloting. Auxiliary controls which are needed in flight are, therefore, often integrated into, or attached to, the controls where the hands are maintained during piloting operations. They are usually near or under where the hands are positioned during flight to allow for the switches to be operated without needing to remove the hand from the respective control and with a minimum of movement. In this way, the switches can be readily adjusted or operated by the user while maintaining full piloting control. This is not just used in aircraft, but in the operation of ground vehicles as well. A similar arrangement many people are familiar with, for example, is the inclusion of switches related to cruise control or sound system operation in a passenger car being located on the steering wheel so a user does not need to take their hands from the wheel to operate them.
While including switches on control sticks, grips, wheels, and the like is obviously highly beneficial, there is only a limited amount of space on these objects. Thus, there can only be a limited number of switches present along with the associated wiring and circuitry necessary for them to operate. While electrical components can be, and have, been successfully miniaturized over the years, it is often hard to shrink the human access component (the switch head) as humans are still relatively similar in size and have only so much control over fine motor movement. As machines have become more and more complex, and it has become more and more desirable to include additional functionality at the fingertips, so to speak, switches have had to be able to provide for more individually detectable human actions in the same space, while also making sure that the human operator operates the switches with certainty. That is, the switch provides feedback to them that the action they intended to engage is actually the one they are engaging. This latter element is often provided by switches having a visible or tactile indicator when they are in particular position and/or have moved from one position to another. For example, most switches “snap” where it is easier to hold them in a specific position than to move them between positions.
One way to have switches provide more actions is to provide infinitely variable switches. These, however, typically cannot provide distinct positions as their infinite variability effectively eliminates their ability to provide feedback as to any specific position that they are in. Thus, instead of providing infinitely variable switches, switches are often provided which have multiple distinct positions where those positions can be moved between with each position activating a different circuit switch and each position being individually detectable (typically by tactile sensation) to a human user. Technically, all switches have multiple positions in that they have at least two positions, one for on and one for off. However, this is really a single position switch. Multiple-position switches, as that term is used herein, typically refer to switches having more than one “on” position. Specifically, each “on” position acts as an “on” for a different circuit switch with the “off” position corresponding to “off” for all the circuit switches.
One such multiple-position switch is the five-position switch. A five-position switch, as the name implies, typically has five distinct “on” positions as well as a home or “off” position. As indicated, a five-position switch ideally requires a distinct amount of force to move the switch to each of the five “on” positions so as to all the user know when it is in each of them by tactile sensation and, should the user release tension on the human activation component, the switch may automatically return to the home position where no circuit switches are activated or may need to be “snapped” back to the home position. It should be noted that in a five position switch, the important aspect is that each position corresponds to a new circuit switch being closed. Previously closed circuit switches do not need to be opened when a new one is closed. This allows for each individual circuit switch activation to activate or do something new.
While multiple-position switches can have virtually any number of positions, five-position switches are a clearly valuable form of multiple-position switches as there was traditionally a very clear way to provide the five positions. Namely, a center lowered (or plunge) position, and then the four cardinal points (up, down, left, and right from center) corresponded to the five on positions while the center raised position was the home “off” position. Similarly, three position switches are also logical as they can use a center plunge position with either up and down or left and right positions creating the three on positions and the center raised position corresponding to off. Because of the inherent logic of three and five positions in 3-dimensional space, many existing and new applications call for three or five-position switches. However, traditional three and particularly five-position switches have been unable to provide circuit redundancy in a sufficiently small space as the movement positions require substantial construction to activate the circuit switches underlying them.
The following is a summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not intended to identify key or critical elements of the invention or to delineate the scope of the invention. The sole purpose of this section is to present some concepts of the invention in a simplified form as a prelude to the more detailed description that is presented later.
There is described herein, among other things, a multi-position switch that can include multiple redundancy at each position. Specifically, the multi-position switch is a five-position switch with all five positions in-line and with double or triple redundancy at each position
Based on the above, there is a need in the art to provide for multiple position switches where a user has definitive points of on and off switching which are used to turn multiple redundant internal circuit switches on and off to provide for increased reliability of switch operation. It is also desirable for the multiple positions of the multiple position switch to be in-line.
There is described herein, among other things, a multi-position switch comprising: a switch head; a button support attached to said switch head and configured to rotate to a first detent position located on a first side of a center position and a second detent position located on a second side opposing said first side of said center position; a first piston shaft connected to said button support and connected to a first roller positioned in a first rocker; a second piston shaft connected to said button support and connected to a second roller positioned in a second rocker; a first circuit switch arranged so as to be switched when said first rocker is rotated by said first roller as said button support rotates to said first detent position; a second circuit switch arranged so as to be switched when said second rocker is rotated by said second roller as said button support rotates to said second detent position; and a plunger located between said first piston shaft and said second piston shaft where depression of said button support in said center position causes said plunger to switch a third circuit switch.
In an embodiment of the multi-position switch, the first circuit switch is one of a plurality of switches switched when said first rocker is rotated by said first roller as said button support rotates to said first detent position.
In an embodiment of the multi-position switch, the second circuit switch is one of a plurality of switches switched when said second rocker is rotated by said second roller as said button support rotates to said second detent position.
In an embodiment of the multi-position switch, the third circuit switch is one of a plurality of switches switched by said plunger when said button support in said center position is depressed.
In an embodiment of the multi-position switch, the button support is configured to rotate from said first detent position to a third detent position located on said first side of said center position.
In an embodiment, the multi-position switch further comprises: a fourth circuit switch arranged so as to be switched when said first rocker is rotated by said first roller as said button support rotates to said third detent position;
In an embodiment of the multi-position switch, the button support is configured to rotate from said second detent position to a fourth detent position located on said second side of said center position.
In an embodiment, the multi-position switch further comprises: a fifth circuit switch arranged so as to be switched when said second rocker is rotated by said second roller as said button support rotates to said fourth detent position.
In an embodiment of the multi-position switch, the fourth circuit switch is one of a plurality of switches switched when said first rocker is rotated by said first roller as said button support rotates to said third detent position.
In an embodiment of the multi-position switch, the fifth circuit switch is one of a plurality of switches switched when said second rocker is rotated by said second roller as said button support rotates to said fourth detent position.
In an embodiment of the multi-position switch, the plunger includes a lower paddle portion and an upper tab, said upper tab interfacing with a plurality of detents on said button support as said button support moves from said center position to said first detent position and from said center position to said second detent position.
In an embodiment of the multi-position switch, the lower paddle portion includes a lower segment and a narrower upper segment.
The following detailed description and disclosure illustrates by way of example and not by way of limitation. This description will clearly enable one skilled in the art to make and use the disclosed systems and methods, and describes several embodiments, adaptations, variations, alternatives and uses of the disclosed systems and methods. As various changes could be made in the above constructions without departing from the scope of the disclosures, it is intended that all matter contained in the description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
While this disclosure will utilize terms such as “above”, “below”, “forward”, “back”, “left” or “right” these terms are used as a matter of convenience to describe the typical arrangement of a device when interacted with by a human user and are not intended to imply an absolute direction relative to the Earth or other body. For example, while a first object which is “below” a second object will typically be closer to the earth than the second object in routine operation, this is not intended to be required as the devices herein could be oriented in any direction relative to the Earth or relative to any gravitational field (or without one, such as in deep space). Instead, these terms are used to show relative positioning of objects to each other. Thus, if a third object was “above” the second object in the prior example, the three objects would typically be arranged generally linearly from the first object, to the second object, to the third object regardless of the various objects' positions in space. Similarly, an object on the right would be on a generally opposing side to an object on the left and movement forward would be in the generally opposing direction to movement backward.
The switch of
At the lower portion of the housing, there are mounted a number of circuit switches (201), (203), (205), (207), (209), (211), (213), (215), (217) and (219). In the depicted embodiment, there are ten such circuit switches (201), (203), (205), (207), (209), (211), (213), (215), (217) and (219) depicted. As this is a five-position switch, each “on” position will activate two of the circuit switches (201), (203), (205), (207), (209), (211), (213), (215), (217) and (219) compared to other positions which provides each position with double redundancy. The circuit switches (201), (203), (205), (207), (209), (211), (213), (215), (217) and (219) are paired with circuit switches (201) and (211) being together, circuit switches (203) and (213) being together, circuit switches (205) and (215) being together, circuit switches (207) and (217) being together, and circuit switches (209) and (219) being together. It should be apparent that each pair of switches could be replaced by a single circuit switch, or by three or more circuit switches if a different level of redundancy is desired. Each of the circuit switches (201), (203), (205), (207), (209), (211), (213), (215), (217) and (219) will generally comprise a micro or sub-micro button switch such as, but not limited to, the B1 basic series of switches or the B3 basic series of switches produced by Otto. This particular type of switch is, however, by no means required and any sort of circuit switch activated by the motion of the switch (100) discussed herein may be used.
The head (101) typically has five different linear positions into which it may be placed. In
The switch (100) will now be discussed in conjunction with the various internal components. The structure of the internals of the switch (100) are best seen by Examining the series of
There is further provided an alternative embodiment which is provided in
As can be seen in
The central portion of the button connector (17) includes a generally concave lower surface (401) having three generally semi-circular divots (411), (413), and (415) therein. The central divot (411) is typically located in generally the center of the concave lower surface (401) with each of divots (413) and (415) being arranged on the forward and backward side thereof. Under the concave lower surface (401) there is positioned a plunger (20) which, in the embodiment of
In the alternative embodiment of
In both embodiments, the upper tab (412) typically includes a generally semi-circular top surface (424) which is generally dimensioned to have a radius similar to the radius of the divots (411), (413) and (415). The plunger (20) is positioned above a compression coil or wave spring (9) which serves to bias the plunger (20) toward the button connector (17) and away from circuit switches (209) and (219) which are positioned below the lower edge (429) of the paddle portion (402) or (1402). There is a central stabilizing pin (4) which runs through a raceway (441) in the plunger (20) allowing the plunger (20) to move up and down against the spring (9) in a straight line. The pin (4) extends through the pistons (30) and (31) and is typically attached to the housing (16) to act as an axis of rotation for the button connector (17) relative to the housing (16) via the pistons (30) and (31).
Below each of the rollers (331) and (333) there is positioned a rocker (351) and (353). The rockers (351) and (353) are of distinctly different shape but have some common design features. Each rocker (351) and (353) is supported on two pins (361) or (363) which are typically rigidly attached to the housing (16) as shown for pins (361) in
Each rocker (351) and (353) include a concave upper surface forming a track (371) and (373) into which the respective roller (331) and (333) is positioned and can roll. The track (373) will typically have steeper surfaces as well as potentially longer surfaces than track (371) as is visible from comparing
Track (371) will typically include a first area (381) forming the lowest area. There is then a slightly raised portion or “bump” (382) followed by the higher area (383). This structure is by no means required, but it can improve the feel of movement as discussed later. This structure of track (371) provides multiple areas where the roller (331) can be. The roller (331) can be in the first area (381) where it is stable and pushed toward center by the track (371) and spring (331), it can be rolling up the raised portion (382) where the spring (321) will typically serve to try and push it back toward the first area (381), it can be on the far side of the raised portion (382) where it will be pushed toward the higher area (383), or will be in the higher area (383). Track (373) will typically include a first area (391) which acts as a sort of bowl at the lowest area of the track (373) and the steep sides (393). It may also include a raised area or bump between them in another embodiment.
Operationally the switch (100) will provide for five different “on” positions. These correspond to depressing the pair of circuit switches (201) and (211); (203) and (213); (205) and (215); (207) and (217); or (209) and (219) and a single “off” or home position.
It should be apparent, that movement from the home position of
If the user continues to push the head (101) in the forward direction, it will place the head (101) into the far forward configuration of
In the far forward position, as can be seen in
From the far forward position of
While
Regardless of position (near forward, far forward, near backward, or far backward), it should be apparent that the circuit switches associated with each position activate simultaneously. Thus, with double redundancy, the circuit switches in each pair (201) and (211); (203) and (213); (205) and (215); (207) and (217); or (209) and (219) are being depressed by the respective rocker at essentially the same time. Further, in order to increase redundancy, additional circuit switches may be placed beside either of the existing circuit switches in any or all of pair (201) and (211); (203) and (213); (205) and (215); (207) and (217); or (209) and (219) to produce additional redundancy at any position.
The fifth position of the switch (100) is produced with the head (101) centered as shown in
As can also be seen from
In the embodiment of the present FIGS, the plunge position which the paddle (402) of the plunger (20) depressing the circuit switches (209) and (219) is only available when the head (101) is centered as in
While the invention has been disclosed in conjunction with a description of certain embodiments, the detailed description is intended to be illustrative and should not be understood to limit the scope of the present disclosure. As would be understood by one of ordinary skill in the art, embodiments other than those described in detail herein are encompassed by the disclosed invention. Modifications and variations of the described embodiments may be made without departing from the spirit and scope of the invention.
It will further be understood that any of the ranges, values, properties, or characteristics given for any single component of the present disclosure can be used interchangeably with any ranges, values, properties, or characteristics given for any of the other components of the disclosure, where compatible, to form an embodiment having defined values for each of the components, as given herein throughout. Further, ranges provided for a genus or a category can also be applied to species within the genus or members of the category unless otherwise noted.
Finally, the qualifier “generally,” and similar qualifiers as used in the present case, would be understood by one of ordinary skill in the art to accommodate recognizable attempts to conform a device to the qualified term, which may nevertheless fall short of doing so. This is because terms such as “circular” are purely geometric constructs and no real-world component is truly “circular” in the geometric sense. Variations from geometric and mathematical descriptions are unavoidable due to, among other things, manufacturing tolerances resulting in shape variations, defects and imperfections, non-uniform thermal expansion, and natural wear. Moreover, there exists for every object a level of magnification at which geometric and mathematical descriptors fail due to the nature of matter. One of ordinary skill would thus understand the term “generally” and relationships contemplated herein regardless of the inclusion of such qualifiers to include a range of variations from the literal geometric meaning of the term in view of these and other considerations.
This application claims benefit of U.S. Provisional Patent Application No. 63/161,203 filed Mar. 15, 2021, the entire disclosure of which is herein incorporated by reference.
Number | Date | Country | |
---|---|---|---|
63161203 | Mar 2021 | US |