The invention relates to the field of micro-electromechanical systems (MEMS) for electrical switching, and in particular to a piezoelectrically actuated latching relay with liquid metal contacts.
Liquid metals, such as mercury, have been used in electrical switches to provide an electrical path between two conductors. An example is a mercury thermostat switch, in which a bimetal strip coil reacts to temperature and alters the angle of an elongated cavity containing mercury. The mercury in the cavity forms a single droplet due to high surface tension. Gravity moves the mercury droplet to the end of the cavity containing electrical contacts or to the other end, depending upon the angle of the cavity. In a manual liquid metal switch, a permanent magnet is used to move a mercury droplet in a cavity.
Liquid metal is also used in relays. A liquid metal droplet can be moved by a variety of techniques, including electrostatic forces, variable geometry due to thermal expansion/contraction and magneto-hydrodynamic forces.
Conventional piezoelectric relays either do not latch or use residual charges in the piezoelectric material to latch or else activate a switch that contacts a latching mechanism.
Rapid switching of high currents is used in a large variety of devices, but provides a problem for solid-contact based relays because of arcing when current flow is disrupted. The arcing causes damage to the contacts and degrades their conductivity due to pitting of the electrode surfaces.
Micro-switches have been developed that use liquid metal as the switching element and the expansion of a gas when heated to move the liquid metal and actuate the switching function. Liquid metal has some advantages over other micro-machined technologies, such as the ability to switch relatively high powers (about 100 mW) using metal-to-metal contacts without micro-welding or overheating the switch mechanism. However, the use of heated gas has several disadvantages. It requires a relatively large amount of energy to change the state of the switch, and the heat generated by switching must be dissipated effectively if the switching duty cycle is high. In addition, the actuation rate is relatively slow, the maximum rate being limited to a few hundred Hertz.
An electrical relay is disclosed that uses a conducting liquid in the switching mechanism. In the relay, a pair of moveable switching contacts is attached to the free end of a switch bar and positioned between a pair of fixed contact pads. Each contact supports a droplet of conducting liquid, such as a liquid metal. A piezoelectric actuator is energized to move the switch bar in a lateral direction and close the gap between one of the fixed contact pads and one of the switching contacts, thereby causing conducting liquid droplets to coalesce and form an electrical circuit. At the same time, the gap between the other fixed contact pad and the other switching contact is increased, causing conducting liquid droplets to separate and break an electrical circuit.
The novel features believed characteristic of the invention are set forth in the claims. The invention itself, however, as well as the preferred mode of use, and further objects and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in conjunction with the accompanying drawing(s), wherein:
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail one or more specific embodiments, with the understanding that the present disclosure is to be considered as exemplary of the principles of the invention and not intended to limit the invention to the specific embodiments shown and described. In the description below, like reference numerals are used to describe the same, similar or corresponding parts in the several Views of the drawings.
The electrical relay of the present invention uses a conducting liquid, such as liquid metal, to bridge the gap between two electrical contacts and thereby complete an electrical circuit between the contacts. Two moveable electrical contacts, which will be referred to as switching contacts, are attached to the free end of a switch bar and positioned between a pair of fixed contact pads. A surface of each contact supports a droplet of a conducting liquid. In the preferred embodiment, the conducting liquid is a liquid metal, such as mercury, with high conductivity, low volatility and high surface tension. A piezoelectric actuator is configured to push or pull the switch bar in a lateral direction, thereby moving the switching contacts so that a first switching contact moves towards a first fixed contact pad. Magnetorestrictive actuators, such as Terfenol-D, that deform in the presence of a magnetic field may be used as an alternative to piezoelectric actuators. In the sequel, piezoelectric actuators and magnetorestrictive actuators will be collectively referred to as “piezoelectric actuators”. This causes the conducting liquid droplets on the contacts to coalesce and complete an electrical circuit between the first switching contact and the first fixed contact pad. Since the switching contacts are placed between the fixed contact pads, as the first switching contact moves towards the first fixed contact pad, the second switching contact moves away from the second fixed contact pad. After the switch-state has changed, the piezoelectric actuator is de-energized and the switching contacts return to their starting positions. The conducting liquid droplets remain coalesced in a single volume because the volume of conducting liquid is chosen so that surface tension holds the droplets together. The electrical circuit is broken again by energizing the piezoelectric actuator to move the first switching contact away from the first fixed contact pad to break the surface tension bond between the conducting liquid droplets. The droplets remain separated when the piezoelectric actuator is de-energized, provided there is insufficient liquid to bridge the gap between the contacts. The relay is amenable to manufacture by micro-machining techniques.
When the switch bar 112 is displaced in a first direction, the first switching contact 114 is moved towards the first fixed contact 122, and the second switching contact 116 is moved away from the second fixed contact 124. When the gap between the contacts 116 and 124 is great enough, the conducting liquid is insufficient to bridge the gap between the contacts and the conducting liquid connection 142 is broken. When the gap between the contacts 116 and 122 is small enough, the liquid droplets 140 coalesce with each other and form an electrical connection between the contacts. The liquid volume is chosen so that when the actuator is de-energized and the switch bar returns to its undeflected position, the coalesced droplets 140 remain coalesced and the separated droplets 142 remain separated. In this way the relay is latched into the new switch-state. The switch state can be returned to that shown in
The use of mercury or other liquid metal with high surface tension to form a flexible, non-contacting electrical connection results in a relay with high current capacity that avoids pitting and oxide buildup caused by local heating.
A top view of the circuit substrate 102 is shown in FIG. 4. Signal traces 128, 134 and 136 connect to fixed contact pads 126, 122 and 124 respectively. The traces are covered with a material that the conducting liquid does not wet, so as to prevent unwanted transfer of conducting liquid. Upper ground traces 130 are positioned on either side of the signal traces to provide electrical shielding. Vias 150 provide electrical connections from the upper ground traces 130 to lower ground traces 132 so that ground currents can surround the signal currents upstream and downstream of the switching structure. All bends in the traces are less than 45° to minimize reflections. Additional circuit traces (not shown) to supply control signals to the actuator may also be formed on the circuit substrate. Alternatively, the actuator may be connected through suitable circuit routing, pads and solder balls on the bottom of the substrate.
In one mode of operation, the contact pad 126 serves as a common terminal and a signal connected to the terminal is switched to either contact pad 122 or contact pad 124 by motion of the actuator 112.
While the invention has been described in conjunction with specific embodiments, it is evident that many alternatives, modifications, permutations and variations will become apparent to those of ordinary skill in the art in light of the foregoing description. Accordingly, the present invention is intended to embrace all such alternatives, modifications and variations as fall within the scope of the appended claims.
This application is related to co-pending application Ser. No. 10/011,056, “Latching Relay with Piezoelectrically Activated Switch Bar”, which is hereby incorporated herein by reference.
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