A variety of applications, such as electric vehicles, require the use of contactors and relays to control the opening and closing of various electric power lines. Under certain conditions, electric vehicles and/or other electric equipment can generate audible noise.
In a first aspect, an electromagnetic switch includes: a stationary electrical contact; a moveable electrical contact; an actuated member to which the moveable electrical contact is attached for driving the moveable electrical contact into and out of contact with the stationary electrical contact; and a damping interface between the moveable electrical contact and the actuated member.
Implementations can include any or all of the following features. The damping interface is cylindrical. The damping interface is toroidal. The damping interface comprises an O-ring seated in a circumferential groove inside an opening of the moveable electrical contact through which the actuated member passes. The damping interface has a K-shape profile facing the actuated member. The damping interface has a chevron-shape profile facing the actuated member. The damping interface comprises a flexure diaphragm. The flexure diaphragm comprises a rubber washer, wherein an outer periphery of the rubber washer is attached to the moveable electrical contact inside an opening of the moveable electrical contact through which the actuated member passes, and wherein an inner periphery of the rubber washer is attached to the actuated member. The electromagnetic switch further includes a friction damper attached to the moveable electrical contact, the friction damper positioned between the moveable electrical contact and a sidewall of the electromagnetic switch. The friction damper is positioned by a metal member on which the moveable electrical contact sits. The friction damper comprises a first member biasing against the moveable electrical contact, and a second member biasing against the sidewall. The first and second members are essentially parallel and oriented in a direction that the moveable electrical contact is being driven. The first member is attached to the moveable electrical contact, and wherein the second member extends from the first member toward the sidewall. The first and second members are essentially antiparallel and orthogonal to a direction that the moveable electrical contact is being driven. One end of the friction damper is attached to the moveable electrical contact and another end biases against the sidewall.
In a second aspect, a method includes: providing a stationary electrical contact for an electromagnetic switch; attaching a moveable electrical contact to an actuated member for driving the moveable electrical contact into and out of contact with the stationary electrical contact; and providing a damping interface between the moveable electrical contact and the actuated member.
Implementations can include any or all of the following features. The method further includes providing a circumferential groove inside an opening of the moveable electrical contact through which the actuated member passes, wherein the damping interface comprises an O-ring seated in the circumferential groove. The damping interface comprises a rubber washer, and the method further includes attaching an outer periphery of the rubber washer to the moveable electrical contact inside an opening of the moveable electrical contact through which the actuated member passes, and attaching an inner periphery of the rubber washer to the actuated member. The method further includes attaching a friction damper to the moveable electrical contact, the friction damper positioned between the moveable electrical contact and a sidewall of the electromagnetic switch.
This document describes examples of damping an electromagnetic switch to reduce or eliminate unwanted oscillatory effects. These oscillatory effects are facilitated by mechanical resonances. In the switch, a moveable contact has some degree(s) of freedom to move relative to the shaft to which it is attached and relative to the stationary electrical contacts against which it is pressed when in the closed position. This shaft-contact joint can be dampened in one or more ways to address the problem of noise generated by the switch during operation. By increasing the damping above a threshold, one can eliminate the unwanted oscillatory effect generated by the moveable contact. Such a threshold is the point where the energy absorbed by the damper during each cycle of oscillation is greater than the energy added by the force generated by flowing DC current acting in conjunction with the motion of the moveable contact. While DC is mentioned as an example, it is believed that oscillation can occur with any current (i.e., also AC) that is sufficiently large. That is, the flow of current in conjunction with the motion of the contact is adding energy to the unwanted motion whether or not the current has a vibratory component.
The electromagnetic switch 100 has a moveable contact 102 that is configured to be moved into and out of contact with stationary contacts 104A-B. For example, the stationary contacts can be considered positive (+) and negative (−) terminals, respectively, of an electric circuit. In a closed position, the moveable contact forms an electric path between the stationary contacts. For example, this can allow a current to flow from one of the stationary contacts to the other.
The electromagnetic switch 100 has a solenoid 106 that actuates a shaft 108, or any other type of actuated member. Particularly, the solenoid interacts with an armature that is connected to the shaft 108 inside the solenoid, and thereby drives the shaft. The moveable contact 102 is attached to the shaft. For example, an opening for the shaft is formed in the moveable contact. The opening can be a hole that extends through the entire thickness of the moveable contact, as in the current example.
The reciprocal motion of the shaft and the moveable contact can be facilitated by one or more springs. In some implementations, the moveable contact is spring loaded. For example, a helical spring 110 is here placed around the shaft 108 on the outside of the solenoid, between the moveable contact 102 and the top of the solenoid.
A damping interface is provided between the shaft and the moveable contact. Examples of damping interfaces are described below.
The annular damper 202 is here essentially cylinder shaped with a lip extending radially outward. For example, the lip can reduce the occurrences of the annular damper moving along the shaft as a result of the reciprocal motion of the moveable contact. For example, the annular damper could otherwise have a tendency to walk down the shaft as the contact is repeatedly being driven into and out of contact with the stationary electric contacts, which contacts are not shown here for simplicity. With or without the lip(s), the annular damper can be dimensioned to be friction fit inside the opening 204.
The annular damper can be manufactured from any material that is suitable based on the intended use of the annular damper to dampen resonance that leads to oscillation of an electromagnetic switch. For example, the annular damper can be made of rubber having a durometer low enough to provide substantial damping, yet high enough that the annular damper is not so deformed by the forces involved that it is dislocated during normal operation.
The moveable contact is located between sidewalls 208. The sidewalls can be made of any suitable insulating material, including, but not limited to, plastic or a ceramic material.
In operation, the shaft 206, actuated by a solenoid or other device, will drive the moveable contact in reciprocal motion relative to stationary contacts. In such motion, a certain amount of play can occur between the contact and the shaft. For example, in various phases of the stroke the contact can slide about along the shaft. The contact can also or instead have some rotational freedom about the shaft. For example, when the damping interface is rotationally symmetric with regard to the shaft, the damping interface can provide useful reduction or elimination of oscillation in several or all of the different positions that the moveable contact assumes relative to the shaft.
The O-rings will serve to dampen oscillation in the moveable contact and the shaft during operation. The O-ring can be made from any suitable material, including, but not limited rubber. The O-ring 302A is here hollow whereas the O-ring 302B is solid. In other implementations, more than one O-ring can be hollow, and/or more than one O-ring can be solid. As another example, the contact can have only a single O-ring, or can have more than two O-rings.
The cylindrical member can have a friction fit inside the contact opening to stay in place. In some implementations, the member 400 can be seated in a recess of the contact, in analogy with the groove 304 (
In operation, the flexure washer can be flexed as a result of play between the moveable contact and the shaft. Here, the moveable contact is shown in a lower position, and a corresponding upper position is indicated in phantom. In other implementation, the amount of flexing can be different that in this example.
Some implementations can substantially reduce the amount of oscillation generated in an electromagnetic switch. For example, the present inventors have proposed the explanation that unwanted noise in an electromagnetic relay under high current is caused by current-driven vibrations in the moveable contact during operation. Some testing has therefore been performed. The electromagnetic switch used in this testing was one that was known to exhibit significant audible noise generation in test situations. The following are results of the testing.
The testing presented in this graph was performed on the unmodified relay; that is, without the damping interface. The relay is powered and closed during the duration of the test. Initially, the power supply for the circuit that included the high power terminals of the relay was off, and the graph indicates zero voltage starting at zero seconds. At approximately six seconds, the power supply was turned on, and the switch began conducting current. The voltage initially dropped from zero to about negative 0.25V, after which it settled to a relatively constant level at a first point 800. That is, the relatively steady voltage starting at this moment indicates that no substantial vibration is occurring.
At approximately 13 seconds into the graph, however, the electromagnetic switch was deliberately perturbed by rapping the exterior case of the relay with a metal tool at a point 802. This caused the relay to vibrate audibly, and measured voltage to rapidly oscillate, first down to about negative 0.3V, and thereafter so somewhat higher negative values, which is reflected by a pattern 804 in the chart. The pattern indicates that the resistance in the moveable contact is quickly fluctuating within essentially a band of oscillating values, which reflects oscillation in the electromagnetic switch. At approximately 21 seconds into the graph, the power supply was turned off, and the oscillation therefore ended.
In this instance the testing indicated that the resonance in question was an angular motion about a line passing through the two contact points between the moveable bar and each of the stationary contacts. As such, the restoring force that causes this motion to exhibit resonant behavior would be the result of compression of the spring resulting from an angular displacement of the bar for the rest position and the profile of the contacting electrode faces.
A damping member was then created that is in principle analogous to one of, or a combination of, the implementations described above. After the damping member was added and the relay was again assembled, testing was repeated to evaluate the impact of the damping.
At a point 1002, about 13 seconds into the graph, the housing was rapped with the metal tool. The impact caused a momentary voltage drop, much as it did at the point 802 in
Several additional impacts 1004 were made on the housing using the metal tool, and each time the resulting voltage behavior was essentially consistent with that of the initial impact at the point 1002. That is, despite repeated perturbations of the system, the electromagnetic switch did not enter the state of significant oscillation as was shown in the previous figures, and no audible vibration was detected. This testing indicated that the resonance which facilitated the oscillation was dampened.
The dampened behavior observed in this testing is evident in the voltage measurements also over very short time periods.
In the above examples, oscillation in electromagnetic switch was eliminated by way of a damping interface between the moveable contact and the driving shaft which reduced the resonant response of the system and thereby suppressed the oscillation. Oscillation can be reduced or avoided in one or more other ways. In some systems, a damping interface as described herein can be used in connection with one or more such other ways of countering oscillation. In other systems, the other oscillation countermeasure(s) can be used without the specific damping interface.
For example, the friction damper can be manufactured from a somewhat wider strip than the member 1206, and the sides can be trimmed so that only the members 1202-04 remain attached to the member 1206. Thereafter, the members 1202-04 can be bent into the position shown, optionally with a contour, for example as shown. That is, the member 1202 can be curved in the general direction of the moveable contact—that is, inward over the metal plate. Similarly, the member 1204 can be curved toward the sidewall; that is, outward from the metal plate. As another example, the members 1202-04 can be formed as one or more separate pieces that are then attached to the member 1206.
In
In
A number of implementations have been described as examples. Nevertheless, other implementations are covered by the following claims.