This application relates generally to the field of microelectromechanical systems (MEMS) and in particular to improved MEMS actuator configurations and switches constructed therefrom.
Microelectromechanical systems (MEMS) are small, movable, mechanical structures built using well-characterized, semi-conductor processes. Advantageously, MEMS can be provided as actuators, which have proven to be very useful in many applications.
Present-day MEMS actuators quite small, having a length of only a few hundred microns, and a width of only a few tens of microns. Such MEMS actuators are typically configured and disposed in a cantilever fashion. In other words, they have an end attached to a substrate and an opposite free end which is movable between at least two positions, one being a neutral position and the others being deflected positions.
Electrostatic, magnetic, piezo and thermal actuation mechanisms are among the most common actuation mechanisms employed MEMS. Of particular importance is the thermal actuation mechanism.
As is understood by those skilled in the art, the deflection of a thermal MEMS actuator results from a potential being applied between a pair of terminals, called “anchor pads”, which potential causes a current flow elevating the temperature of the structure. This elevated temperature ultimately causes a part thereof to contract or elongate, depending on the material being used.
One possible use for MEMS actuators is to configure them as switches. These switches are made of at least one actuator. In the case of multiple actuators, they are typically operated in sequence so as to connect or release one of their parts to a similar part on the other. These actuators form a switch which can be selectively opened or closed using a control voltage applied between corresponding anchor pads on each actuator.
MEMS switches have many advantages. Among other things, they are very small and relatively inexpensive—depending on the configuration. Because they are extremely small, a very large number of MEMS switches can be provided on a single wafer.
Of further advantage, MEMS switches consume minimal electrical power and their response time(s) are extremely short. Impressively, a complete cycle of closing or opening a MEMS switch can be as short as a few milliseconds.
Although prior-art MEMS actuators and switches have proven to be satisfactory to some degree, there nevertheless remains a general need to further improve their performance, reliability and manufacturability.
We have developed improved MEMS structures employing movable conductive member and a number of current-carrying stationary contact terminals which advantageously permits higher current carrying capability that prior art devices in which currents flowed through movable conductive members. Advantageously, and in sharp contrast to the prior art, our inventive structures may carry currents in excess of 1.0 amp without the need for additional current limiting devices. Consequently, systems employing our inventive structures exhibit significantly lower overall system manufacturing costs.
Viewed from a first aspect, the present invention is directed to MEMS actuators and switches useful for a variety of applications including high current ones.
Viewed from another aspect, the present invention is directed to MEMS actuators and switches constructed therefrom wherein the actuators move in directions not disclosed in the prior art, i.e., perpendicular to a planar substrate upon which they are anchored.
Viewed from yet another aspect, the present invention is directed to MEMS actuators and switches exhibiting a hybrid combination of directional movements, i.e., structures including elements that move in directions parallel to a substrate surface and elements which move perpendicular to those substrate surfaces.
A more complete understanding of the present invention may be realized by reference to the accompanying drawing in which:
a and 2b are side views of actuators employed by the MEMS switch of
a through 5g schematically show an example of the relative movement of the MEMS actuators when the MEMS switch goes from an “open position” to a “closed position”,
a and 6b shows a schematic of yet another alternate embodiment of the exemplary MEMS switch of
The following merely illustrates the principles of the invention. It will thus be appreciated that those skilled in the art will be able to devise various arrangements which, although not explicitly described or shown herein, embody the principles of the invention and are included within its spirit and scope.
Furthermore, all examples and conditional language recited herein are principally intended expressly to be only for pedagogical purposes to aid the reader in understanding the principles of the invention and the concepts contributed by the inventor(s) to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions.
Moreover, all statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof. Additionally, it is intended that such equivalents include both currently known equivalents as well as equivalents developed in the future, i.e., any elements developed that perform the same function, regardless of structure.
Thus, for example, it will be appreciated by those skilled in the art that the diagrams herein represent conceptual views of illustrative structures embodying the principles of the invention.
When the MEMS switch (100) is in a closed position, the contact terminals (102, 104) are electrically engaged—that is to say an electrical current may flow between the two contact terminals (102,104). This electrical engagement is realized when the movable conductive member (106) electrically “shorts” the pair of contact terminals (102, 104).
Conversely, when the MEMS switch (100) is in an open position, the contact terminals (102, 104) are not electrically engaged and no appreciable electrical current flows between them. In preferred embodiments, the movable conductive member (106) is gold plated.
It should be noted that in
We have discovered that that using contact terminals (102, 104) such as those shown and a movable conductive member (106) allows the conducting of higher currents than MEMS devices in which an electrical conducting path goes along a length of the MEMS actuators (10, 10′) themselves. Advantageously, and as a direct result of our inventive MEMS structure (100), it is now possible to employ MEMS switches while—at the same time—avoid using current limiters. As a result, overall manufacturing costs of systems employing MEMS switches may be significantly reduced.
Turning our attention now to
Referring back to
In each actuator (10, 10′), the spaced-apart portions (22, 22′) are substantially parallel and connected together at a common end (26, 26′) that is shown opposite the anchor pads (24, 24′) and overlying the substrate (12).
Each of the actuators (10, 10′) also comprises an elongated cold arm member (30, 30′) adjacent and substantially parallel to the corresponding hot arm member (20, 20′). Each cold arm member (30, 30′) has, at one end, an anchor pad (32, 32′) connected to the substrate (12) and a free end (34, 34′) that is opposite the anchor pad thereof (32, 32′). The free ends (34, 34′) overlie the substrate (12).
The cold arm member (30) of the first actuator (10) has two portions (31). The free end (34) of the second actuator (10′) is the location from which extends an extension arm (130′). The extension arm (130′) is itself provided with a side extension arm (132′) at its free end. It should be noted that the hot arm member (20′) and the cold arm member (30′) of the second actuator (10′) can be made longer than what is shown in the figure. It is thus possible to omit the extension arm (130′) and connect the side extension arm (132′) directly on the side of the free end (34′) or even elsewhere on the second actuator (10′).
A dielectric tether (40, 40′) is attached over the common end (26, 26′) of the portions (22, 22′) of the hot arm member (20, 20′) and over the free end (34, 34′) of the cold arm member (30, 30′). The dielectric tether (40, 40′) is provided to mechanically couple the hot arm member (20, 20′) and the cold arm member (30, 30′) and to keep them electrically independent, thereby maintaining them in a spaced-apart relationship with a minimum spacing between them to avoid a direct contact or a short circuit in normal operation as well as to maintain the required withstand voltage, which voltage is proportional to the spacing between the corresponding members (20, 30 and 20′, 30′).
It should be noted that the maximum voltage used can be increased by changing of the ambient atmosphere. For instance, the use of high electro-negative gases as ambient atmosphere would increase the withstand voltage. One example of this type of gases is Sulfur Hexafluoride, SF6.
The dielectric tether (40, 40′) is preferably molded directly in place at the desired location and is attached by direct adhesion. Direct molding further allows having a small quantity of material entering the space between the parts before solidifying. Advantageously, the dielectric tether (40, 40′) may be attached to the hot arm member (20, 20′) and the cold arm member (30, 30′) in a different manner than the one shown in the figures. Moreover, the dielectric tethers (40, 40′) can be transparent as illustrated in some of the figures.
Each dielectric tether (40, 40′) is preferably made entirely of a photoresist material. A suitable material for that purpose, which is also easy to manufacture, is the material known in the trade as “SU-8”. The SU-8 is a negative, epoxy-type, near-UV photo resist based on EPON SU-8 epoxy resin (from Shell Chemical). Of course, other photoresist may be used as well, depending upon the particular design requirements. Other possible suitable materials include polyimide, spin on glass, oxide, nitride, ORMOCORE™, ORMOCLAD™ or other polymers. Moreover, combining different materials is also possible and well within the scope of the present invention. As can be appreciated, providing each dielectric tether (40, 40′) over the corresponding actuator (10, 10′) is advantageous because it allows using the above-mentioned materials, which in return provides more flexibility on the tether material and a greater reliability.
In use, when a control voltage is applied at the anchor pads (24, 24′) of the hot arm member (20, 20′), a current travels into the first and second portions (22, 22′). In the various embodiments illustrated herein, the material(s) comprising the hot arm members (20, 20′) is/are sufficiently conductive so that it increases in length as it is heated. The cold arm members (30, 30′), however, do not substantially exhibit such elongation since no current is initially passing through them.
In the embodiment depicted in
The second actuator (10′) is designed and configured to deflect its free end (34′) sideways when a potential is applied to its anchor pads (24′). In this manner, the first set of actuators and this second set of actuators move perpendicular to one another. More specifically, and as shown in this figure, the first actuator moves in a direction substantially perpendicular to the plane of the underlying substrate (towards/away-down/up) while his second actuator moves in a plane parallel to the surface plane of the substrate. Of course, the use of the “first” and “second” are only exemplary.
Continuing with the discussion of
According to an aspect of the present invention, it is advantageous to provide at least one of these additional dielectric tethers (50′) so as to provide additional strength to the hot arm member (20′) bu redicomg tjeor effective length thereby preventing distortion of the hot arm member (20′) over time. Since the gap between the parts is extremely small, the additional tethers (50′) reduce the risks of a short circuit happening between the two portions (22′) of the hot arm member (20′) or between the portion (22′) of the hot arm member (20′) that is closest to the cold arm member (30′) and the cold arm member (30′) itself by keeping them in a spaced-apart configuration. Additionally, since the two portions (22′) of the hot arm member (20′) are relatively long, they tend to distort when heated to produce the deflection, thereby decreasing the effective stroke of the actuators (10′). The additional dielectric tethers (50′) advantageously alleviate this problem.
As can be appreciated, using one, two or more additional dielectric tethers (50′) has many advantages, including increasing the rigidity of the portions (22′) of the hot arm member (20′), increasing the stroke of the actuators (10′), decreasing the risks of shorts between the portions (22′) of the hot arm members (20′) and increasing the breakdown voltage between the cold arm members (30′) and hot arm members (20′).
The additional dielectric tethers (50′) are preferably made of a material identical or similar to that of the main dielectric tethers (40′). Small quantities of materials are advantageously allowed to flow between the parts before solidifying in order to improve the adhesion. In addition, one or more holes or passageways (not shown) can be provided in the cold arm members (30′) to receive a small quantity of material before it solidifies to ensure a better adhesion.
As may be seen in
a through 5g schematically show an example of the relative movement of the MEMS actuators (10, 10′) when the MEMS switch (100) goes from an “open position” to a “closed position”, thereby closing the circuit between the two contact terminals (102, 104). To move from one position to the other, the actuators (10, 10′) are operated in sequence.
More particularly,
f shows the effect of control voltage in the first actuator (10) being released, which causes support arm (108) to engage the bottom side of the side extension arm (132′) of the second actuator (10′) as it returns towards its neutral position. The peg (132a′) is then retained in the hole (109) The, as shown in
As can be observed from these figures, as soon as the movable conductive member (106) is moved, it is urged against the contact terminals (102, 104) and the circuit is closed. The closing of the MEMS switch (100) is very rapid, all this occurring in typically a few milliseconds. As can be appreciated, the MEMS switch (100) may be opened by reversing the above-mentioned operations.
a illustrates an alternate embodiment. This embodiment is similar to the one illustrated in
b shows that when the actuators of a same pair will be set to their “closed” position, the side extension arm (132′) of the actuator closer to the first actuator will be displaced of the distance “d′”. This distance (d′) is greater than the distance (d) between the tip of the side extension arm (132′) and the edge of the support arm (108) of the first actuator.
As may be understood by those skilled in the art, stiction can be generally defined as a retention force urging the conductive member (106) to stay on the contact terminals (102, 104). Microwelding is one possible cause of stiction, especially if the conductive member (106) stays in contact with the contact terminals (102, 104) for a long period of time. The “cold” arm member (30) then becomes a “hot” arm member when a potential is applied and this generates a positive force pushing up the conductive member (106) to break the contact. The pushing force is added to the natural spring force of the actuator (10). This feature can be used with any of the other possible designs, provided that electric insulation is provided at an appropriate location to insulate the parts. The main tether (40) of the first actuator (10) can also be used to insulate the support arm (108) from the base of the first actuator (10).
It is understood that the above-described embodiments are illustrative of only a few of the possible specific embodiments which can represent applications of the invention. Numerous and various other arrangements and materials may be made by those skilled in the art without departing from the spirit and scope of the invention.
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Number | Date | Country | |
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20080223699 A1 | Sep 2008 | US |