The subject matter herein relates generally to electrical relay devices.
Electrical relay devices are generally electrically operated switches used to control the presence or absence of current flowing through a circuit from a power source to one or more other electrical components. The power source may be one or more batteries, for example. Some electrical relays use an electromagnet to mechanically operate a switch. The electromagnet may physically move a movable electrical contact relative to one or more stationary contacts. The movable electrical contact may form or close a circuit (allowing current to flow through the circuit) when the movable contact engages one or more of the stationary contacts. Moving the movable electrical contact away from the stationary contact(s) breaks or opens the circuit.
At least some electrical relay devices include a ferromagnetic element that is disposed at least proximate to the electromagnet such that an induced magnetic field applies a magnetic force upon the ferromagnetic element that translates the ferromagnetic element relative to the electromagnet. The ferromagnetic element is coupled to a shaft, which extends from the ferromagnetic element to the movable electrical contact. The shaft is coupled to both the ferromagnetic element and the movable electrical contact. Therefore, movement of the ferromagnetic element due to the induced electrical field causes movement of the shaft and the movable electrical contact towards and away from the stationary contacts, forming or braking a circuit, as described above.
Known electrical relay devices have some disadvantages. For example, the coupling between the shaft and the ferromagnetic element in some known electrical relay devices is made via a separate fastener. An additional fastener is used to couple the shaft to the moving electrical contact. The particular fasteners used in some known relay devices are retaining rings, such as E-clips or C-clips. But, since the retaining rings are separate fasteners that are installed to engage to discrete parts, the retaining rings are prone to moving out of position, and even falling off of the parts completely. The electrical relay devices may be used on vehicles, such as trains and automobiles. Vibrations and other forces encountered during use and/or improper installment during assembly may cause the retaining rings to loosen, dislodge, and finally fall off. At such time, the shaft may uncouple from the ferromagnetic element and/or the movable electrical contact. In either event, the movable electrical contact would no longer be coupled, indirectly via the shaft, to the ferromagnetic element, such that translation of the ferromagnetic element would not control movement of the movable electrical contact and the electrical relay device would cease to function until the fasteners or new fasteners are replaced.
A need remains for an electrical relay device that does not use separate fasteners to couple the shaft to the movable electrical contact and to the ferromagnetic element.
In an embodiment, a carrier sub-assembly for an electrical relay device is provided that includes a plunger and a shaft. The plunger is formed of a ferromagnetic material. The plunger has a generally cylindrical shape extending between a top side and a bottom side of the plunger. The shaft extends between a contact end and an opposite plunger end. The shaft is directly secured to the plunger without a discrete component between the shaft and the plunger securing the shaft to the plunger. The shaft and the plunger are configured to move together within the electrical relay device. A segment of the shaft including the contact end protrudes from the top side of the plunger for securing to a movable contact of the electrical relay device.
In another embodiment, an electrical relay device is provided that includes a housing, two stationary contacts, a coil of wire, and an actuator assembly. The stationary contacts are held within the housing and spaced apart from one another. The coil of wire is within the housing and is electrically connected to a relay power source. The actuator assembly is disposed partially within the coil of wire within the housing. The actuator assembly includes a movable contact coupled to a carrier sub-assembly. The actuator assembly is configured to move along an actuation axis between a first position and a second position based on a presence or absence of a magnetic field induced by current through the coil of wire. The movable contact of the actuator assembly is spaced apart from the stationary contacts when the actuator assembly is in the first position. The movable contact engages the stationary contacts to provide a closed circuit path between the stationary contacts when the actuator assembly is in the second position. The carrier sub-assembly includes a plunger and a shaft directly secured to one another without a discrete component between the shaft and the plunger securing the shaft to the plunger. The plunger is formed of a ferromagnetic material. The shaft protrudes from a top side of the plunger and extends to a contact end. The contact end of the shaft is directly secured to the movable contact without a discrete component between the shaft and the movable contact securing the shaft to the movable contact. The contact end of the shaft is defined by at least two deflectable prongs that extend through an aperture in the movable contact.
The electrical relay device 100 includes a housing 106 and various components within the housing 106. The relay device 100 includes two stationary contacts 108 held within the housing 106. The stationary contacts 108 are spaced apart from one another to prevent current from flowing directly between the two stationary contacts 108. The relay device 100 further includes a coil 110 of wire within the housing 106. The wire coil 110 is electrically connected to a relay power source 112, which provides electrical energy to the wire coil 110 in order to induce a magnetic field. The relay power source 112 is operated to selectively control the magnetic field induced by the current through the wire coil 110. In an embodiment, the wire coil 110 is spaced apart from the stationary contacts 108 within the housing 106. For example, the wire coil 110 in the illustrated embodiment is disposed proximate to a mounting end 114 of the housing 106 in an electromagnetic region 116 of the housing 106. The stationary contacts 108, on the other hand, are disposed more proximate to a top end 118 of the housing 106 within an electrical circuit region 120 of the housing 106. As used herein, relative or spatial terms such as “top,” “bottom,” “front,” “rear,” “left,” and “right” are only used to distinguish the referenced elements and do not necessarily require particular positions or orientations in the electrical relay device 100 or in the surrounding environment of the electrical relay device 100.
The electrical relay device 100 further includes an actuator assembly 122 within the housing 106. The actuator assembly 122 is disposed partially within the wire coil 110. The actuator assembly 122 includes a movable contact 124 that is coupled to a carrier sub-assembly 126. The movable contact 124 is coupled to the carrier sub-assembly 126 such that the movable contact 124 moves with the carrier sub-assembly 126. The movable contact 124 is located within the electrical circuit region 120 of the housing 106, while part of the carrier sub-assembly 126 is located within the electromagnetic region 116, surrounded by the wire coil 110. In an embodiment, the actuator assembly 122 is configured to move along an actuation axis 128 between a first position and a second position based on a presence or absence of a magnetic field induced by current through the wire coil 110. The actuator assembly 122 moves along the actuation axis 128 by translating towards and away from the top end 118 of the housing 106, for example. The actuator assembly 122 is moved by a magnetic force that acts upon the carrier sub-assembly 126. For example, when the relay power source 112 applies a current to the wire coil 110, the current through the wire coil 110 induces a magnetic field that acts on the portion of the carrier sub-assembly 126 located within the electromagnetic region 116 of the housing 106, causing the carrier sub-assembly 126 and the movable contact 124 coupled thereto to move along the actuation axis 128. When the current from the relay power source 112 ceases, the wire coil 110 no longer induces the magnetic field that acts upon the carrier sub-assembly 126, and the actuator assembly 122 returns to a starting position.
The position of the actuator assembly 122, and the movable contact 124 thereof, is controlled by the relay power source 112, which controls the supply of current to the wire coil 110 to induce the magnetic field. For example, the actuator assembly 122 may be in the open circuit position in response to the relay power source 112 not supplying electrical current to the wire coil 110 or in response to the relay power source 112 supplying an electrical current to the wire coil 110 that has insufficient voltage to induce a magnetic field capable of moving the actuator assembly 122 to the closed circuit position. The actuator assembly 122 may be moved to the closed circuit position in response to the relay power source 112 providing an electrical current to the wire coil 110 that has sufficient voltage to induce a magnetic field that moves the actuator assembly 122 to the closed circuit position. The relay power source 112 may provide between 2 and 20 V of electrical energy to the wire coil 110 in order to move the actuator assembly 122 from the open circuit position to the closed circuit position. In an embodiment, the relay power source 112 provides 12 V of electrical energy to move the actuator assembly 122. By comparison, the system power source 102 may provide electrical energy through the electrical relay device 100 at higher voltages, such as at 120V, 220V, or the like. The flow of current from the relay power source 112 to the wire coil 110 is selectively controlled to selectively operate the electrical relay device 100. For example, the relay power source 112 may be actuated by a human operator and/or may be actuated automatically by an automated controller (not shown) that includes one or more processors or other processing units.
The carrier sub-assembly 126 includes a plunger 132 and a shaft 134. The plunger 132 defines a channel 136 that extends axially through the plunger 132 between a top side 138 and a bottom side 140 of the plunger 132. The shaft 134 is held within the channel 136 of the plunger 132. The shaft 134 is directly secured to the plunger 132. As used herein, two components are “directly secured” to one another when the two components mechanically engage one another and are fixed to one another without any discrete components between the two components that are used to secure the two components together. Examples of such discrete components include fasteners that are separate from the shaft 134 and the plunger 132, such as E-clips and C-clips (which are prone to dislodging due to vibration and/or other forces encountered during use).
The shaft 134 and the plunger 132 are configured to move together within the electrical relay device 100 along the actuation axis 128. The shaft 134 extends between a contact end 142 and an opposite plunger end 144. The shaft 134 extends through the channel 136 of the plunger 132 such that a segment of the shaft 134 protrudes from the top side 138 of the plunger 132. The segment of the shaft 134 protruding from the top side 138 includes the contact end 142 of the shaft 134. The shaft 134 secures to the movable contact 124 at or proximate to the contact end 142. The movable contact 124 is spaced apart from the plunger 132 along the actuation axis 128. In an embodiment, the shaft 134 directly secures to the plunger 132 at or proximate to the plunger end 144, and the shaft 134 directly secures to the movable contact 124 at or proximate to the contact end 142. The shaft 134, the plunger 132, and the movable contact 124 of the actuator assembly 122 are configured to move together along the actuation axis 128 towards and away from the stationary contacts 108.
In an embodiment, the movable contact 124 is disposed within the electrical circuit region 120 of the housing 106, the plunger 132 is disposed within the electromagnetic region 116 of the housing 106, and the shaft 134 extends into both the electrical circuit region 120 and the electromagnetic region 116. For example, the contact end 142 of the shaft 134 is within the electrical circuit region 120, and the plunger end 144 is within the electromagnetic region 116. The electrical relay device 100 may further include a core plate 148 that is coupled to the housing 106 and fixed in place relative to the housing 106. The core plate 148 may define at least part of a divider wall 156 between the electrical circuit region 120 above and the electromagnetic region 116 below. The core plate 148 defines an opening 150 that receives the shaft 134 therethrough. The shaft 134 extends through the opening 150 of the core plate 148 such that the contact end 142 is above a top side 152 of the core plate 148 and the plunger end 144 is below a bottom side 154 of the core plate 148. The core plate 148 is disposed between the movable contact 124 and the plunger 132. In an embodiment, the top side 138 of the plunger 132 is configured to engage the bottom side 154 of the core plate 148 when the actuator assembly 122 is in the closed circuit position, as shown in
The plunger 132 may be surrounded by the coil 110 of wire. For example, the plunger 132 is disposed within a passage 146 that is radially interior of the wire coil 110. The plunger 132 is 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 an induced magnetic field by the wire coil 110. In an embodiment, the shaft 134 is formed of a metal material that is different than the ferromagnetic material of the plunger 132. For example, the ferromagnetic material of the plunger 132 has a greater magnetic permeability than the metal material of the shaft 134. As used herein, magnetic permeability refers to a degree of magnetization that a material obtains in response to an applied magnetic field. The metal material of the shaft 134 optionally may be aluminum, titanium, zinc, or the like, or an alloy such as stainless steel or brass.
The shaft 134 is directly secured to the plunger 132 without using any intervening discrete components, such as bolts, screws, C-clips, E-clips, and other fasteners, and also adhesives that provide a chemical bond. The shaft 134 may be held within the channel 136 of the plunger 132 via an interference fit. The shaft 134 may additionally or alternatively be secured within the channel 136 via flanges on the shaft 134 that mechanically engage corresponding shoulders and/or surfaces of the plunger 132. In the illustrated embodiment, the shaft 134 includes an end flange 158 at the plunger end 144. The end flange 158 has a greater diameter than the channel 136 at the bottom side 140 of the plunger 132. As a result, the end flange 158 engages the bottom side 140 of the plunger 132. The end flange 158 abuts the bottom side 140, which prohibits the shaft 134 from moving axially relative to the plunger 132 (for example, from being pulled out of the channel 136) in a direction from the bottom side 140 towards the top side 138 of the plunger 132. In another embodiment, the end flange 158 is configured to engage a bottom shoulder 212 (shown in
In an embodiment, the shaft 134 is directly secured to the movable contact 124 at or proximate to the contact end 142 such that no intervening fastener is used to secure the shaft 134 to the movable contact 124. In the illustrated embodiment, the contact end 142 of the shaft 134 is defined by at least two deflectable prongs 162. The prongs 162 are configured to extend through an aperture 164 in the movable contact 124. The prongs 162 have catch surfaces 186 (shown in more detail in
The contact end 142 of the shaft 134 is defined by at least two deflectable prongs 162. The shaft 134 includes three deflectable prongs 162 in the illustrated embodiment, but other embodiments may include two prongs 162 or more than three prongs 162. The prongs 162 define a cavity 178 therebetween. The deflectable prongs 162 each have a fixed end 180 and a free end 182. The fixed ends 180 hold the prongs 162 onto the shaft 134. The free ends 182 of the prongs 162 are supported by the fixed ends 180 and together define the contact end 142 of the shaft 134. The deflectable prongs 162 are configured to deflect radially inward at least partially into the cavity 178. For example, as the contact end 142 of the shaft 134 is loaded through the aperture 164 (shown in
In the illustrated embodiment, the deflectable prongs 162 each include a hook feature 184 at the respective free end 182. The hook feature 184 protrudes radially outward. The hook feature 184 defines a catch surface 186. The catch surface 186 of each hook feature 184 generally faces towards the top side 138 of the plunger 132. In an embodiment, as shown in
The various components shown in
The movable contact 124 has an inner side 198 and an opposite, outer side 200. The inner side 198 of the movable contact faces towards the divider wall 156. The contact spring 190 is configured to engage the inner side 198. As the movable contact 124 is loaded onto the shaft 134 over the contact end 142, the hook features 184 of the deflectable prongs 162 engage the interior walls (not shown) that define the aperture 164 (shown in
In the illustrated embodiment, the plunger 132 defines a broad region 206 of the channel 136 and a narrow region 208 of the channel 136. The broad region 206 extends from the top side 138 of the plunger 132 to the narrow region 208, and the narrow region 208 extends from the broad region 206 towards the bottom side 140 of the plunger 132. The narrow region 208 does not extend fully to the bottom side 140 in the illustrated embodiment because the interior walls 204 define a flared bottom shoulder 212 between the narrow region 208 and the bottom side 140. In an alternative embodiment, however, the narrow region 208 extends fully to the bottom side 140. The broad region 206 has a greater diameter than the narrow region 208. The interior walls 204 of the plunger 132 define a shoulder 210 within the channel 136 that separates the broad region 206 from the narrow region 208.
Optionally, the broad region 206 has a diameter that is greater than a diameter of the segment of the shaft 134 disposed within the broad region 206 such that a radial gap 214 extends between the interior walls 204 of the plunger 132 and the outer surface 202 of the shaft 134. The radial gap 214 may have a ring shape that extends fully around the perimeter of the shaft 134. In an embodiment, the radial gap 214 is configured to receive a portion of the plunger spring 192 (shown in
In the illustrated embodiment, the shaft 134 includes the end flange 158 at the plunger end 144 of the shaft 134, and the shaft 134 also includes an intermediate flange 216 that is spaced apart from end flange 158. For example, the intermediate flange 216 is disposed more proximate to the contact end 142 than the relative location of the end flange 158 to the contact end 142. The intermediate flange 216 is disposed on a segment of the shaft 134 that is received within the channel 136, such that the intermediate flange 216 is located within the channel 136. A narrow segment 218 of the shaft 134 extends between the end flange 158 and the intermediate flange 216. The end flange 158 and the intermediate flange 216 both are stepped radially outward from the outer surface 202 of the shaft 134 along the narrow segment 218. The end flange 158 and the intermediate flange 216 define a recess 220 therebetween. The recess 220 extends axially along the length of the narrow segment 218 and radially between the outer surface 202 of the narrow segment 218 and the outer surface 202 of the end flange 158 and/or the intermediate flange 216.
In an embodiment, the interior walls 204 of the plunger 132 along the narrow region 208 extend into the recess 220 between the end flange 158 and the intermediate flange 216 to secure an axial position of the shaft 134 relative to the plunger 132. For example, the narrow region 208 of the channel 136 may have an axial length that is less than or approximately equal to an axial length of the narrow segment 218 of the shaft 134 such that the interior walls 204 are received within the recess 220. The intermediate flange 216 of the shaft 134 may be configured to engage the shoulder 210 of the plunger 132 within the channel 136 to restrict axial movement of the shaft 134 relative to the plunger 132 in a direction from the top side 138 of the plunger 132 to the bottom side 140. In addition, the end flange 158 may be configured to engage the bottom shoulder 212 (or the bottom side 140) of the plunger 132 to restrict axial movement of the shaft 134 relative to the plunger 132 in an opposite direction from the bottom side 140 to the top side 138. Thus, the narrow region 208 of the channel 136 is received in the recess 220 of the shaft 134, which directly secures the shaft 134 to the plunger 132, effectively mechanically locking the shaft 134 within the channel 136 of the plunger 132. Optionally, the diameter of the narrow region 208 of the channel 136 may be approximately equal to a diameter of the narrow segment 218 of the shaft 134 such that little to no clearance exists between the interior walls 204 of the plunger 132 and the outer surface 202 of the shaft 134. The interior walls 204 engage the outer surface 202, providing an interference fit that supports the coupling of the shaft 134 to the plunger 132.
In an embodiment, the end flange 158 of the shaft 134 is formed in-situ after loading the shaft 134 into the channel 136 of the plunger 132. For example, the shaft 134 may be loaded into the channel 136 from the top side 138 towards the bottom side 140. The plunger end 144 of the shaft 134 may be mechanically flared or spread outward to form the end flange 158 after the shaft 134 is loaded into the channel 136 such that the end flange 158 extends radially outward beyond at least a portion of the bottom shoulder 212, as shown in
In an alternative embodiment, the shaft 134 may be directly secured to the plunger 132 via a threaded coupling. For example, the outer surface 202 of the shaft 134 may define helical threads (not shown) along at least a segment of the shaft 134 that engages the interior walls 204 of the plunger 132 (such as the narrow segment 218 of the shaft 134 shown in
In another alternative embodiment, instead of flaring or spreading the plunger end 144 of the shaft 134 after loading the shaft 134 into the channel 136, the plunger end 144 may be formed to include deflectable prongs (not shown), which may be similar to the prongs 162 at the contact end 142 of the shaft 134. For example, the deflectable prongs at the plunger end 144 may be configured to deflect radially inwards as the prongs are loaded through the channel 136 (such as through the narrow region 208 of the channel 136). Once hook features at ends of the prongs protrude beyond the bottom shoulder 212 and/or beyond the bottom side 140 of the plunger 132, the prongs may resiliently return towards an unbiased position. The prongs returning towards the unbiased position may extend radially outward to engage the bottom shoulder 212 and/or the bottom side 140 to directly secure the shaft 134 to the plunger 132. The prongs at the plunger end 144 may be used in addition to threadably coupling the shaft 134 to the plunger 132, providing an interference fit between the shaft 134 and the plunger 132, and/or other coupling means in order to directly secure the shaft 134 to the plunger 132. In an alternative embodiment, the shaft 134 does not include the deflectable prongs 162 at the contact end 142.
The plunger 132 and the shaft 134 are both at least partially formed of a common metal material. The plunger 132 is formed at least partially of a ferromagnetic material. In one embodiment, the common metal material is a ferromagnetic material, such as iron, nickel, cobalt, and/or an alloy thereof, such that the shaft 134 and the plunger 132 are both formed of the ferromagnetic material. The shaft 134 may be subsequently coated, such as via plating, painting, spraying, or the like, in a second metal material that has a reduced magnetic permeability relative to the ferromagnetic material used to form the shaft 134 and the plunger 132. The second metal material may reduce the magnetic permeability of the shaft 134 without affecting the magnetic permeability of the plunger 132. In another embodiment, the common metal material used to form the plunger 132 and the shaft 134 is either not a ferromagnetic material or is a ferromagnetic material with a relatively low magnetic permeability, such as stainless steel. After the forming process, the plunger 132 may be coated, such as via plating, painting, spraying, or the like, in a second ferromagnetic material that has a greater magnetic permeability than the first ferromagnetic material used to form the shaft 134 and the plunger 132. The second ferromagnetic material may increase the magnetic permeability of the plunger 132 without affecting the magnetic permeability of the shaft 134.
As described herein, the actuator assembly 122 (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 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(f), unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
This application claims priority to U.S. Provisional Application No. 62/174,558, filed 12 Jun. 2015, which is incorporated by reference in its entirety.
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