The subject matter herein relates generally to electromechanical switches (e.g., contactors or relays) that control a flow of electrical power through a circuit.
Electromechanical switches may be used in a number of applications in which it is desirable to selectively control the flow of electrical power (e.g., current). Electromechanical switches, such as contactors or relays, may include a movable contact and a plurality of stationary contacts. The movable contact is selectively moved to engage or disengage the stationary contacts. When the movable contact is engaged to the stationary contacts, electrical power may flow through the contacts. The electrical power may not flow through the contacts when the movable contact is spaced apart from the stationary contacts.
In certain applications, an audible noise is generated along the interfaces between the movable contact and the stationary contacts. For example, an electric vehicle uses an electric vehicle battery (EVB) or a traction battery to power the vehicle. Such batteries may include individual cells having one or more contactors. When an individual presses the accelerator pedal, the movable contact of at least one of the contactors is moved to engage the stationary contacts. If the individual rapidly and/or deeply presses the accelerator pedal to quickly accelerate the vehicle, a surge of current flows through the movable contact and the stationary contacts. This surge of current may cause the movable contact to oscillate and vibrate, which generates the audible noise. The audible noise can be distracting or annoying to individuals within the vehicle as well as to individuals near the vehicle.
Accordingly, a need remains for an electromechanical switch that prevents or at least diminishes the audible noise caused by oscillation of the contacts at the contact interfaces.
In one or more embodiments of the present disclosure, an electromechanical switch is provided that includes a housing, first and second stationary contacts mounted to the housing, a movable contact, and a carrier sub-assembly. The housing has a divider wall. The carrier sub-assembly includes a support rod that extends through an aperture in the divider wall and is coupled to the movable contact. The carrier sub-assembly is configured to move the movable contact relative to the first and second stationary contacts. The carrier sub-assembly includes a contact spring surrounding the support rod between the divider wall and the movable contact. The carrier sub-assembly also includes a dampener in engagement with the contact spring. The dampener is configured to absorb vibration along one or more of the contact spring or the movable contact.
In one or more embodiments of the present disclosure, an armature assembly of an electromechanical switch is provided that includes a movable contact, a support rod, a ferromagnetic plunger, a contact spring, and a dampener. The movable contact has a mating side and a mounting side opposite the mating side. The movable contact defines an opening therethrough. The support rod extends through the opening and couples to the movable contact. The support rod extends through an aperture in a divider wall of the electromechanical switch. The ferromagnetic plunger is coupled to the support rod along an opposite side of the divider wall from the movable contact. The contact spring surrounds the support rod between the movable contact and the divider wall. The dampener surrounds the support rod between the movable contact and the divider wall. The dampener engages the contact spring to absorb vibration along one or more of the contact spring or the movable contact.
In one or more embodiments of the present disclosure, an electromechanical switch is provided that includes a housing, first and second stationary contacts mounted to the housing; a movable contact, and a carrier sub-assembly. The housing has a divider wall. The movable contact has a mating side that faces the first and second stationary contacts and a mounting side opposite the mating side. The carrier sub-assembly is configured to move the movable contact relative to the first and second stationary contacts. The carrier sub-assembly includes a support rod, a contact spring, and a dampener. The support rod extends through an aperture in the divider wall and is coupled to the movable contact. The contact spring surrounds the support rod between the divider wall and the mounting side of the movable contact. The dampener has an O-ring shape and surrounds the support rod. The dampener has a first side in engagement with an end of the contact spring and a second side opposite the first side in engagement with the mounting side of the movable contact. The dampener includes an elastomeric material and is compressible to absorb vibration along one or more of the contact spring or the movable contact.
Embodiments of the present disclosure provide an electromechanical switch, such as a relay or contactor, that is configured to selectively establish and break an electrical connection between a power source and an electrical device. The electromechanical switch may be configured to handle high electrical current, such as 500 Amperes (A) or greater.
At such high levels of electrical power conveyed across a mating interface between mating contacts, the mating contacts of known electromechanical switches are prone to oscillations and/or vibrations, which may generate an audible noise. The audible noise may be interpreted by observers as a high pitch squeal, which may distract and/or annoy the observers. The electromechanical switch according to the embodiments described herein is configured to eliminate the audible noise, or at least reduce the occurrence and magnitude of the noise. For example, the electromechanical switch includes a dampener in engagement with a spring that applies a biasing force on a movable contact. The dampener is configured to absorb oscillations and vibrations of the spring and/or the movable contact.
The electromechanical switch 101 is an electrically operated switch is used to selectively control the presence or absence of current flowing through the power circuit 100 from the load power source 102 to the electrical load 104. The electromechanical switch 101 closes (or establishes) a circuit to allow current to flow through the power circuit 100 from the load power source 102 to the electrical load 104 to power the load 104. The electromechanical switch 101 opens (or breaks) the circuit to stop the flow of current through the power circuit 100 to the electrical load 104. The electromechanical switch 101 may be a relay device or a contactor device.
In one non-limiting example application, the power circuit 100 may be installed within a vehicle, such as a hybrid or fully electric automobile. The load power source 102 may represent or include a battery. The electrical load 104 may represent or include a motor, a heating and/or cooling system, a lighting system, a vehicle electronics system, or the like. The electromechanical switch 101 may also be used to convey electrical current in the reverse direction from the electrical load 104 to the load power source 102 for charging the load power source 102, such as during regenerative braking of the vehicle. In other applications, the power circuit 100 may be utilized in other types of vehicles, such as rail vehicles and marine vessels, in appliances, in industrial machinery, and the like.
The electromechanical switch 101 includes a housing 106, first and second stationary contacts 108, 109, and a movable contact 124. The first and second stationary contacts 108, 109 are mounted to the housing 106 and secured in fixed positions relative to the housing 106. The first stationary contact 108 is spaced apart from the second stationary contact 109. The first stationary contact 108 is electrically connected to the load power source 102, and the second stationary contact 109 is electrically connected to the electrical load 104. The electromechanical switch 101 is shown in
The movable contact 124 includes a mating side 202 and a mounting side 204 that is opposite the mating side 202. The mating side 202 faces the first and second stationary contacts 108, 109. When the electromechanical switch 101 is in a closed position (as shown in
The electromechanical switch 101 further includes a coil 110 of wire (referred to herein as wire coil 110) within the housing 106. The wire coil 110 is electrically connected, via one or more conductive elements 107, to a switch power source 112 which provides electrical current to the wire coil 110 to induce a magnetic field. The switch power source 112 may be operated to selectively control the magnetic field induced by the wire coil 110.
The movable contact 124 is coupled to a carrier sub-assembly 126. The movable contact 124 and the carrier sub-assembly 126 together define an armature assembly 122 of the electromechanical switch 101. The armature assembly 122 moves bi-directionally along an actuation axis 128 relative to the stationary contacts 108, 109. In an embodiment, the movement of the armature assembly 122 may be based on the presence or absence of a magnetic field induced by current through the wire coil 110. For example, responsive to the switch power source 112 supplying current to the wire coil 110, the induced magnetic field acts on the carrier sub-assembly 126 and causes the carrier sub-assembly 126, and the movable contact 124 coupled thereto, to move along the actuation axis 128 towards the stationary contacts 108, 109. In response to the switch power source 112 stopping the current, the armature assembly 122 may axially return towards a starting position due to biasing forces, such as gravity and/or spring forces. Alternatively, the magnetic field induced by the coil 110 may force movement of the armature assembly 122 in the direction away from the stationary contacts 108, 109, which disconnects the movable contact 124 from the stationary contacts 108, 109.
The carrier sub-assembly 126 includes a support rod 134, a plunger 132, a contact spring 130, and a dampener 138. The support rod 134 is elongated between a first end 142 and an opposite second end 144 of the support rod 134. The support rod 134 is coupled to the movable contact 124 at or proximate to the first end 142. For example, the first end 142 may extend through an opening 212 in the movable contact 124 that extends from the mating side 202 to the mounting side 204. The first end 142 may be coupled to the movable contact 124 via a clip 210 that engages the mating side 202 of the movable contact 124. In an alternative embodiment, the first end 142 of the support rod 134 may include deflectable prongs that latch onto the movable contact 124 instead of utilizing the clip 210. The support rod 134 is coupled to the plunger 132 at or proximate to the second end 144. For example, the second end 144 may extend into a channel 136 of the plunger 132 to secure the support rod 134 to the plunger 132 via a clip 214. Alternatively, the support rod 134 may secure to the plunger 132 via an interference fit, one or more deflectable latching features, an adhesive, and/or the like. The plunger 132 is fixedly secured to the support rod 134. The movable contact 124 may be movably coupled to the support rod 134 such that the movable contact 124 is able to move axially relative to the support rod 134 towards the second end 144. The movable contact 124 and the plunger 132 are spaced apart from one another along a length of the support rod 134.
The housing 106 includes a divider wall 156 that is located between the movable contact 124 and the wire coil 110. The housing 106 in the illustrated embodiment is a vessel that defines an interior chamber 174. The divider wall 156 segments the chamber 174 into a contact region 120 and an electromagnetic region 116. The stationary contacts 108, 109 and the movable contact 124 are located at least partially within the contact region 120. For example, the stationary contacts 108, 109 project out of the chamber 174 of the housing 106 to electrically connect to the conductive elements 105. The wire coil 110 is disposed within the electromagnetic region 116.
The armature assembly 122 extends into both the contact region 120 and the electromagnetic region 116. For example, the divider wall 156 defines an aperture 150 extending from a top side 158 of the divider wall 156 through a bottom side 160 of the divider wall 156. As used herein, relative or spatial terms such as “top,” “bottom,” “inner,” “outer,” “upper,” and “lower” are only used to distinguish the referenced elements and do not necessarily require particular positions or orientations in the surrounding environment of the electromechanical switch 101. The support rod 134 extends through the aperture 150. The movable contact 124 and the plunger 132 are located along opposite sides of the divider wall 156. The movable contact 124 is located within the contact region 120, and the plunger 132 is located within the electromagnetic region 116. The armature assembly 122 moves relative to the divider wall 156 along the actuation axis 128.
The plunger 132 within the electromagnetic region 116 is circumferentially surrounded by the wire coil 110. The plunger 132 may be formed of a ferromagnetic material. For example, the plunger 132 may be formed of iron, nickel, cobalt, and/or an alloy containing one or more of iron, nickel, and cobalt. The plunger 132 has magnetic properties that allow the plunger 132 to translate in the presence of the magnetic field induced by the wire coil 110. The movement of the plunger 132 causes the entire armature assembly 122 to move along the actuation axis 128.
The contact spring 130 surrounds the support rod 134. The contact spring 130 is located within the contact region 120 between the movable contact 124 and the divider wall 156. The contact spring 130 is a coil spring in the illustrated embodiment. The contact spring 130 may be compressed between the movable contact 124 and the divider wall 156 to force the movable contact 124 into sustained engagement with the clip 210. The contact spring 130 may directly or indirectly engage the mounting side 204 of the movable contact 124, and may directly or indirectly engage the top side 158 of the divider wall 156. In the illustrated embodiment, the contact spring 130 directly engages the top side 158 of the divider wall 156 and indirectly engages the mounting side 204 of the movable contact 124 via the dampener 138. The dampener 138 is sandwiched between the contact spring 130 and the movable contact 124. As described is more detail herein, the dampener 138 is absorbs and/or dissipates vibration and oscillation of the movable contact 124 and/or the contact spring 130 to eliminate or at least prohibit the generation of an audible noise when the electromechanical switch 101 is in the closed state shown in
The movable contact 124 is conductively coupled to both stationary contacts 108, 109. The movable contact 124 provides a closed circuit path between the two stationary contacts 108, 109. For example, electrical current is allowed to flow between the stationary contacts 108, 109 through the movable contact 124 that forms a conductive bridge. In the illustrated embodiment, in the closed state of the electromechanical switch 101, electrical current from the system power source 102 is conveyed through the contacts 108, 124, 109 to the electrical load 104 to power the load 104. The electromechanical switch 101 may transition to the open state shown in
Although two stationary contacts 108, 109 and one movable contact 124 are shown in
The contact spring 130 is configured to control the spacing between the movable contact 124 and the divider wall 156. For example, the contact spring 130 may force the movable contact 124 into sustained engagement between the clip 210 and the mating side 202 of the movable contact 124. The contact spring 130 is engaged by the dampener 138. The contact spring 130 extends between a contact end 220 of the spring 130 and a structure end 222 of the spring 130. The contact end 220 is at or proximate to the movable contact 124, and the structure end 222 is at or proximate to the top side 158 of the divider wall 156. The contact spring 130 in the illustrated embodiment is a helical coil spring that surrounds the segment of the support rod 134 between the movable contact 124 and the divider bridge 156.
The dampener 138 has a first side 224 and a second side 226 opposite the first side 224. In the illustrated embodiment, the dampener 138 is disposed between the contact spring 130 and the movable contact 124. For example, the first side 224 of the dampener 138 engages the contact end 220 of the contact spring 130, and the second side 226 engages the mounting side 204 of the movable contact 124. The dampener 138 is sandwiched between the contact spring 130 and the movable contact 124. The dampener 138 may at least partially compress or deform due to the forces exerted on the dampener 138 by the spring 130 and the movable contact 124. The dampener 138 absorbs and/or dissipates vibration and oscillation of the spring 130 and/or the movable contact 124. The dampener 138 in the illustrated embodiment circumferentially surrounds the support rod 134.
The structure end 222 of the contact spring 130 in the illustrated embodiment engages the divider wall 156, and the contact end 220 indirectly engages the movable contact 124 via the dampener 138.
The dampener 138 may include one or more elastomeric materials. For example, the dampener 138 may include thermoplastic elastomers, natural rubber, synthetic rubber, silicone, or the like. In one non-limiting example, the elastomeric material may be or include perfluoroelastomer (FFKM). The elastomeric material may provide the dampener 138 with compressible and/or deformable properties, which allow the dampener 138 to reduce vibrations and/or oscillations of the contact spring 130 and/or the movable contact 124.
In another alternative embodiment, the electromechanical switch 101 may have multiple dampeners including a first dampener 130 at the location shown in
The second side 226 of the dampener 138 lacks lips and may be similar to the second side 226 shown 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 example embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of ordinary 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(f), 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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