Patent Grant
7859372
The subject matter herein relates generally to relay assemblies, and more particularly, to methods and apparatus for reducing bounce during mating of a movable relay contact with a stationary relay contact.
Bouncing of relay and switch button-style contacts is a well known phenomenon, and is typically caused by a combination of factors. The factors include the initial impact and rebound of the contacts, flexing of a beam carrying a movable one of the contacts, the impact between an armature plate carrying the beam and a core of the relay, and/or the propagation of the impacts along the contact beam. Contact bouncing can have the effects of creating electrical noise within the system using the relay or switch and/or damaging the contacts themselves. Bouncing breaks and re-makes the electrical connection at and below the millisecond time-frame. That action generates various stages of arcing causing very broadband noise to be imposed on, and radiated to, connected and surrounding electrical systems. This noise can cause many types of malfunctions and interference. Systems using known relays provide filtering and shielding to diminish the interference or malfunction at an increase in the cost of the overall systems.
Damage to the contacts is generally caused by electrical arcing between the contacts when the contacts are separated from one another, such as during the bouncing of the contacts. Damage to the contacts limits the life and sets the maximum switching energy limits of the device. Many special materials have been developed to withstand the damaging effects long enough to achieve an acceptable service life. Increased contact mass, high velocity action and high forces are needed to enable high switching energy ratings. These limit the size, weight and cost reductions that can be achieved.
Conventional relays address the problems associated with contact bouncing by attempting to reduce the amount of bouncing or by using materials that sustain the wear caused by the arcing. These known relays attempt to reduce the amount of bouncing by using a dampening material on at least one of the contact structures to reduce the rebound after initial impact, by providing a counterweight that impacts the beam or contact at the time of rebound, or by counteracting the rebound with a device, such as a spring to hold the contact against rebound. These solutions are complicated and costly, and do not eliminate the bounce between the contacts. Similarly, the known relays that use materials that sustain wear caused by arcing are costly and the material adds bulk and weight to the contacts. As such, a relay assembly is needed that reduces the bouncing phenomenon in a cost effective and reliable manner.
In one embodiment, a relay assembly is provided including a coil and a stationary contact having a first contact surface. At least a portion of the first contact surface defines a wiping contact surface. The relay assembly also includes a movable contact having a second contact surface defining a contact area that engages the first contact surface. The movable contact is moved along a driving path toward the stationary contact when current is passed through the coil, and the movable contact is moved along a rebound path different from the driving path after initial impact with the stationary contact. The stationary contact is oriented or shaped with respect to the movable contact such that the movable contact engages, and wipes against, at least a portion of the wiping contact surface when the movable contact is moved along the rebound path.
Optionally, the first contact surface may be oriented non-coplanar with a plane tangent to an apex of the second contact surface. The wiping contact surface may substantially mirror the rebound path such that the movable contact travels along the wiping contact surface as the movable contact moves along the rebound path. The movable contact may be asymmetrically shaped such that the contact area is off-set with respect to a center of mass of the movable contact. The contact area may be off-set with respect to a center of mass of the movable contact such that the movable contact is rotated along the rebound path after initial impact. Optionally, the relay assembly may include a planar, movable beam, wherein the movable contact is coupled to the beam and moved along the driving path by the beam. The stationary contact may be tilted such that the first contact surface is oriented non-parallel with respect to the plane of the beam when the movable contact initially impacts the stationary contact. The wiping contact surface of the stationary contact may be oriented non-orthogonally with respect to a plane defined by the mounting area. The first contact surface may have a predetermined pitch angle and a predetermined roll angle with respect to a plane of the beam, wherein at least one of the pitch angle and the roll angle are non-zero.
In another embodiment, a relay assembly is provided that includes a stationary contact having a first contact surface that defines a first contact area and a wiping contact surface that extends along the first contact surface from the first contact area. A stationary contact plane is defined tangent to the first contact area, the stationary contact plane extends along a major axis and a minor axis. The relay assembly also includes a movable contact sub-assembly having a movable beam and a movable contact positioned along the beam. The movable contact has a second contact surface defining a second contact area that engages the first contact area when the movable contact is mated with the stationary contact. The movable contact is moved along a driving path by the beam toward the stationary contact, and the movable contact is moved along a rebound path different from the driving path after initial impact with the stationary contact. The stationary contact is tilted about at least one of the major axis and the minor axis such that the movable contact engages the wiping contact surface as the movable contact moves along the rebound path.
In another embodiment, a method is provided of reducing bounce during mating between a movable contact and a stationary contact of a relay assembly. The method includes attaching the movable contact to a movable beam of the relay assembly, such that the movable beam moves the movable contact along a driving path toward the stationary contact. The method also includes orienting or shaping the stationary contact such that the movable contact engages, and wipes against, at least a portion of a wiping contact surface of the stationary contact when the movable contact is moved along a rebound path after initial impact of the movable contact with the stationary contact.
While the figures illustrate the relay 10, it is realized that the subject matter herein may be applicable to other devices, like switches or other types of relays, that have contacts that are closed to complete an electrical circuit and/or contacts that are susceptible to bouncing. The relay 10 is thus provided as merely illustrative and the subject matter herein is not intended to be limited to the relay 10.
The stationary contact 14 includes a first contact surface 30 oriented to engage a second contact surface 32 of the movable contact 12. When the first and second contact surfaces 30, 32 engage one another, the circuit is completed between the contacts 12, 14. The first and second contact surfaces 30, 32 engage one another at first and second contact areas 34, 36, respectively. The first and second contact areas 34, 36 may each be represented by a point on the respective first and second contact surfaces 30, 32. Alternatively, an area of less than approximately ten percent of the first and second contact surfaces 30, 32 may engage one another to define the first and second contact areas 34, 36, and the first and second contact areas 34, 36 may have a generally circular or oval shape, or another curvilinear or non-curvilinear shape. In other alternative embodiments, an area defining a majority of at least one of the first and second contact surfaces 30, 32 may engage one another to define the first and second contact areas 34, 36.
In the illustrated embodiment, the first contact surface 30 is generally planar, while the second contact surface 32 is generally curved. The shape of the curved surface of the second contact surface 32 is selected to allow the movable contact 12 to maintain contact with the first contact surface 30 at, and immediately following, impact. In the illustrated embodiment, the second contact surface 32 has a convex, or outwardly bulging, curved surface that defines an apex 38 opposite to the beam 20.
In operation, when the relay assembly 10 (shown in
During closing of the contacts 12, 14, the movable contact 12 has a dynamic center of gravity. For example, the above factors may cause the center of gravity of the movable contact 12 to shift, which affects the rebound path. One factor that significantly affects the shifting of the center of gravity and the rebound path is having the position of the contact point (e.g. the first and second contact surfaces 34, 36) off-set with respect to a normal center of gravity 44 of the movable contact. The normal center of gravity of the movable contact 12 is the center of mass of the movable contact 12. In the illustrated embodiment, the normal center of gravity 44 is substantially centered with the movable contact 12, such as at point 44, which may be substantially aligned with the apex 38. During closing, the center of gravity remains generally at the normal center of gravity 44. However, after initial impact, the center of gravity is moved generally rearward, such as to the point 46. The shifting of the center of gravity to point 46 is at least partially caused by the contact point of the contacts 12, 14 being off-set with respect to the center of gravity 44 at initial impact. The force of the beam 20 moving along the driving path also forces the center of gravity to shift, as well as other factors. The shifting of the center of gravity, as well as the inertia of the beam 20 and movable contact 12 induces a rotation of the movable contact 12 about the second contact area 36 along the rebound path. The curved surface of the movable contact 12 facilitates such rotation. The rotation generally causes a wiping motion or scrubbing motion that dissipates the energy of the closing. The scrubbing off of the energy substantially eliminates any separation during the rebound. In an exemplary embodiment, the movable contact 12 oscillates along the rebound path until the movable contact 12 comes to rest in the closed position.
In an exemplary embodiment, the stationary contact 14 is oriented with respect to the movable contact 12 such that the second contact surface 32 engages, and wipes against, at least a portion of the first contact surface 30 as the movable contact 12 is moved along the rebound path. For example, at least a portion of the stationary contact 14 is positioned rearward and upward with respect to the initial contact area 34 such that the movable contact 12 engages the first contact surface 30 as the movable contact 12 is moved along the rebound path. The stationary contact 14 is planar and angled with respect to the movable contact 12 to provide interference with the stationary contact 14 as the movable contact moves along the rebound path. For example, in the illustrated embodiment, the stationary contact 14 is oriented non-parallel to the plane defined by the mounting area 28 such that at least a portion of the stationary contact 12 is positioned above the plane tangent to the apex 38, and the movable contact 12 wipes against the stationary contact 14 as the movable contact is moved along the rebound path. The wiping of the movable contact 12 along the stationary contact 14 may reduce and/or eliminate any bounce or separation of the contacts after the initial impact of the movable contact 12 with the stationary contact 14. Separation of the contacts 12,14 may cause arcing damage to the contacts 12, 14. The amount of time that the contacts are separated, the number of separations that occur, and other factors may have an effect on the amount of damage done to the contacts. Reducing or eliminating such bouncing may prolong the life of the contacts and/or the effectiveness of the contacts. The tilting of the stationary contact, which allows wiping and scrubbing off of energy created during the closing of the contacts, reduces or eliminates bouncing.
In operation, when the relay assembly 10 (shown in
The first contact surface 30 also defines a wiping contact surface 52, which is a portion of the first contact surface 30 upon which the movable contact wipes against as the movable contact 12 is transferred along the rebound path. The wiping contact surface 52 extends along a wiping path 54 that may be either linear (such as shown in
In an exemplary embodiment, the stationary contact 14 includes a stationary contact plane 55 that is tangent to the first contact area 34. The stationary contact plane 55 is defined by both a major axis 56 and a minor axis 58. The major axis 56 extends through the first contact area 34 and is oriented generally parallel to the beam axis 26 (shown in
In an exemplary embodiment, and as illustrated in
In an alternative embodiment, the stationary contact 14 is tilted about the major axis 56, such that the stationary contact 14 has either a positive or negative roll angle. The stationary contact 14 may be rolled in addition to, or in lieu of, being pitched. The roll angle provides at least a portion of the first contact surface 30 above the first contact area 34, such that the movable contact 12 engages, and moves along, the wiping contact surface 52 of the stationary contact 14. In another alternative embodiment, the stationary contact 14 may be provided with a negative pitch angle. In such an embodiment, the initial contact area on the stationary contact 14 may be located forward of a final contact area, such that the movable contact is wiped along the wiping contact surface 52 from the initial contact area to the final, closed position of the contacts 12, 14. Such an embodiment may reduce bouncing by reducing the initial impact of the movable contact 12 and the stationary contact 14 by allowing the movable contact 12 to continue generally along the driving path in a downward and rearward direction.
In other alternative embodiments, stationary contacts having other non-planar first contact surfaces. The shape may be complex to accommodate a complex rebound path of a corresponding movable contact.
In an exemplary embodiment, the shape of the movable contact 112 dictates a contact area 126 of the movable contact 112. For example, the contact area 126 (or contact point in some embodiments depending on the shape and material of the contacts) may be proximate the portion of the movable contact 112 having a maximum width. The contact area 126 is generally off-set with respect to the center of mass 124, which creates an eccentric impact between the movable contact 112 and the stationary contact 114. For example, the off-set causes the movable contact to rotate or roll about the center of mass after initial impact, which is generally shown by arrow H. The eccentric movement causes a scrubbing or wiping between the contacts 112, 114 which reduces or eliminates any bounce between the contacts 112, 114.
In an exemplary embodiment, such as illustrated in
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. 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, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
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| Number | Date | Country | |
|---|---|---|---|
| 20090107814 A1 | Apr 2009 | US |
