Flexible circuit piezoelectric relay
An arrangement of a flex circuit relay 7 is provided. The flex circuit relay 7 has a first substrate 10. A first connective member 24 is connected on the first substrate 10. A second flexible substrate 20 is provided having a contact portion 30 spaced away from the first substrate 10 in a first position and being spaced adjacent to the first substrate 10 in a second position. A second conductive member 26 is provided on the second substrate 20 for making contact with the first conductive member 24. A piezoelectric actuator 28 is connected with the second substrate 20 to cause the second substrate contact portion 30 to move between the first and second positions.
The present invention relates to flexible circuits and more particularly to flexible circuits utilized in the automotive industry which can additionally incorporate relays for circuits.
In the most recent quarter century the utilization of electronics in automotive vehicles has increased significantly. For example virtually all automotive vehicles have an engine control module to optimize the performance of the engine with regard to fuel efficiency and environmental emissions. Inflatable restraints have been added to enhance occupant safety in a crash situation. Advanced braking systems, such as anti-skid braking and traction control further enhance safe operation of the vehicle. Other electrical systems have been added or enhanced to increase the comfort of the vehicle. The above mentioned additions and enhancements have resulted in a more complex wiring system which supplies power and signal transfer to and from various electrical components and controllers. Currently, much of the power and signaling requirements of a vehicle are supplied by hard conductive wiring, which is housed in a wiring harness. Fabrication of a wiring harness is a very labor intensive operation. Installation and/or repair of a wiring harness can also be very time consuming and expensive. Another disadvantage associated with the hard copper conductive wiring is the cost associated with the copper. For certain applications the copper wire needed to provide for signal transfer at a low electrical load can be provided by a copper wire of a very small cross-sectional area. However, a minimum diameter of copper wiring is not determined by its electrical requirements. The minimum diameter of the wiring is determined by its frailty during the assembly process of the wiring harness and of the wiring of the vehicle.
To reduce the cost of automotive wiring harnesses a new type of electrical conduit has been provided. This new conduit is typically referred to as a flexible circuit. In a flexible circuit, a polymeric (or insulated metallic ribbon) substrate which is flexible, provides support for the various electrical conductor lines. The electrical conductors are then supplied by a foil that is affixed to the flexible substrate. Another flexible layer of polymeric material can cover the conductors on the flexible substrate.
The utilization of flexible circuits as a replacement for the prior wiring harnesses has been limited due to the particular problems faced by flexible circuits at the various component interfaces. For instance, the interface of the flexible circuit with a fuse box has been a particular limiting factor. To overcome those limitations, an inventive contact method has been provided in U.S. patent application Ser. No. 09/298240 filed Apr. 22,1999. Other examples of connector interfaces for flexible circuits can be found in a review of U.S. Pat. Nos. 5,885,091 and 5,969,418.
Another problem with the utilization of flexible circuits is in the use of relays. Relays are typically switches that have two contacts which are spring biased toward or away from each other, and are activated (closed or opened) by an electromagnetic force by a selectively excitable electromagnetic coil. Relays are typically provided for high current applications that require momentary application. Relays are commonly self-contained entities that contain a coil and contacts. Relays are typically prepackaged to a predetermined physical footprint. The design of relays is mostly controlled by their manufacturers and users of such relays adapt their circuits to predesigned physical specifications. Two major elements in the design of relays are the generation of high current contact heat between the contacts, and the amount of current which is allowed in the exciting coil which is typically of a much lower current. Because of the current capabilities of the contacts of the relay, most relays have a solid post with a relatively high mass. The relay coil is typically specified to be excited by a low current and therefore has very low mass copper wires. When connecting the relay to a conventional circuit board the high relative mass of the relay terminals provides a relatively large heat sink so that lots of heat is required to assemble the relay to the remainder of the circuit. This heat required for assembly is typically within the limits of a rigid circuit board. However, with a flexible circuit no such rigid circuit board is provided and items such as relays which require a high heat input are difficult to assemble to the flexible circuit. Providing the heat required for many relays causes the flexible circuit to become warped and deformed.
Prior to the present invention, to accommodate the heat of assembly the flexible circuit often has to be redesigned to be a non-planar structure with a much larger mass than desirable. Such a modification of the flexible circuit diminishes its many advantages. Flexibility of the flexible circuit is especially important in applications of engine control modules which often have physically large circuits which are folded over for placement within a mounting box to conserve space within the engine compartment of the vehicle.
It is desirable to provide a flexible circuit which allows for the relatively higher current contacts in connecting one circuit to another that is typically required in the utilization of a relay without having a flexible circuit with an increased mass which will diminish its characteristics of flexibility. It is furthermore even more desirable to have an arrangement of a flex circuit relay which can eliminate the requirements of a coil member.
SUMMARY OF INVENTIONIn a preferred embodiment an arrangement of a flex circuit relay is provided. A first substrate is provided which may be a flex circuit or a conventional rigid circuit board. A pair of gapped conductive members which may be tracings or surface mounted devices are also provided connected on the first substrate. A second flexible substrate is provided. The second flexible substrate is supported away from the first substrate. The second substrate has a contact portion. Connected to the contact portion is a conductive member which may be a connective member provided by an etched conductor or by a surface mounted device.
In a first position with respect to the first substrate, the contact portion of the second substrate is spaced away from the first substrate. In a second position with respect to the first substrate, the contact portion of the second substrate is spaced adjacent to the first substrate. A piezoelectric actuator is connected to the second substrate which enables the second substrate contact portion to move between the first and second positions with respect to the first substrate. When moved to the second position adjacent to the first substrate, the second conductive member bridges the gap between the pair of conductive members of the first substrate to complete the circuit. The flex circuit relay of the present invention can be configured to be normally on or normally off.
An advantage of the present invention is that the piezoelectric actuator eliminates the use for a coil and provides a relay typically having a much thinner profile than a relay device which utilizes a coil.
Other features and advantages of various embodiments of the present invention will become more apparent to those skilled in the art from the reading of the following detailed description and upon reference to the drawings.
BRIEF DESCRIPTION OF DRAWINGS
Connected on the first substrate is a conductive elevator 12. The elevator 12 may be a portion of FR-4 or CEM circuit board material. The elevator 12 as shown is a surface mounted device which comprises a flat chip resistor. Other suitable surface mounted devices are capacitors, inductors, fuses, shunts and other various other electrical elements. The elevator surface mounted device 12 has an aluminous substrate 14. The elevator surface mounted device has two outer post terminals or end caps 16.
Supported by two elevators 12 (only one shown in
A preferred material for the second substrate 20 is polyamide. Polyamide is often preferable for soldering electrical devices to the second substrate 20. When a conductive adhesive is utilized to connect electrical devices to the second substrate 20 in lieu of soldering, polyester has been found to be suitable.
The second substrate 20 can also include other materials such as PVDF and Teflon. Furthermore, the second substrate 20 can be a metal foil ribbon which is insulated by a post-lamination process, or by use of an adhesive which is used to bond a conductive member to the second substrate 20. However, when metal is utilized it must be thin enough to ensure the proper flexible properties.
The second substrate 20 has an under bent portion 22 to aid its cantilever support arrangement upon the elevator 12.
In other embodiments (not shown), the second substrate may be wrapped around the elevator, and an adhesive layer may be employed to hold the elevator to the second substrate. Also the flexible second substrate may be mounted to a top surface of the elevator and interfaced to a plated through hole which is in turn interfaced to the lower substrate.
Connected to the first substrate 10 is a pair of conductive members 24 which are gapped away from each other. The conductive members 24 may be a membrane as shown, or surface mounted devices as described in co-pending U.S. patent application Ser. No. 09/777,982. As shown, the conductive members 24 are a foil or powder copper which has been etched out in a circuit desired pattern.
In other embodiments (not shown), the conductive member 24 materials can include aluminum or unsolderable materials such as aluminum or aluminum alloy which is cladded over copper. The copper will allow an electrical component to be attached to the conductive member by soldering although aluminum is being relied upon to perform the conductive function.
Connected to the second substrate 20 is a second conductive member 26. The conductive member 26 may be a membrane as shown or may be a surface mounted device.
Connected to a side of the second substrate 20 generally opposite the first substrate 10 is a piezoelectric actuator 28. In other embodiments (not shown) the piezoelectric actuator 28 may be positioned on a side of the second substrate adjacent to the first substrate (underneath the second substrate) or may be sandwiched inside the second substrate itself. As shown, the piezoelectric actuator 28 is a film piezoelectric or a ceramic piezoelectric. If utilizing a ceramic piezoelectric actuator, the actuator may be multi-layered having a middle layer of lead zircornate titanate (PZT). Above and below the PZT layer is a high temperature polymide adhesive layer called LaRC—SI. The bottom LaRC—SI layer is adhesively joined to a thin layer of stainless steel. The top LaRC—SI layer is joined to a layer of aluminum. Such devices are typically referred to as a thin layer unimorph ferroelectric driver and sensor. Such devices are made under the tradename Thunder by Face International Corporation, Norfolk, Va. However, other suitable piezoelectric actuators may be utilized.
The second substrate has a contact portion 30. The contact portion 30 is covered by the second conductive member 26. In a first position, the contact portion 30 is spaced away from the first substrate 10. In a second position, the contact portion 30 is spaced adjacent to the first substrate 10. The piezoelectric actuator 28 moves the second substrate 20 to move the contact portion 30 between the first and second positions.
In the second position (shown in phantom) the second conductive member 26 electrically connects the conductive members 24 together to complete a circuit. Typically, the actuator 28 will be excited by a voltage source which is delivered by an etched conductive path 32 which also travels along the bent portion 22 of the second substrate 20 to make contact with at least one of the end caps 16 of the elevator 12 and thereafter to make contact with etched conductive path 36 provided on the first substrate.
It is to be noted that the second substrate 20 can have two separate gapped conductive members which when brought adjacent to the first substrate 10 are connected by a connective member placed on the substrate 10. The flex circuit relay arrangement of
An alternate preferred embodiment relay arrangement 37 is provided in
The configuration of
The configuration of
The piezoelectric actuators 40, 42 can also be configured to make the second substrate 38 bow upwards as shown in the upper phantom line when actuated. In an alternative the piezoelectric actuators 40, 42 may naturally cause the second substrate to bow upwards and straighten out the second substrate 38 when actuated. If an appropriate circuit is added the relay arrangement 37 can be such that after the patch 58 has been pushed downward by an operator causing a connection between conductive members 50, 56 and 54. An appropriate circuit may be latched to cause the piezoelectric actuators 40, 42 to deform to raise the patch 58 vertically upward. Accordingly the operator of the vehicle can feel the raised patch 58 and have tactile feedback confirmation that actuation of the circuit has occurred.
The embodiment of
The flex circuit relay arrangement 67 offers several advantages. The first advantage is that since both flex substrates can be actuated to move toward one another the relay can be made to be more sensitive. A conductive member 98 can connect with conductive member 94 and a conductive member 100 may be connected with conductive member 96 to complete a circuit by contact of the conductive members 94, 96. The flex circuit relay arrangement 67 has the logic options of the flex circuit arrangement 37 and additionally can be made such that the connection between connective members 94, 96 will only occur if actuator 78 is excited and actuator 88 is not excited. Alternatively, it can be arranged that actuator 78 alone will cause a connection; however actuator 88 alone will not cause such a connection between the connective members 94, 96.
In still other embodiments actuators 78, 88 must both be excited for a connection to be made or they can be normally engaged and require the excitation of one of the other or both of the piezoelectric actuators 78, 88 to be excited for the conductive members 94, 96 to disengage. Additionally substrates 74 and 86 may be portions of a continuous sheet which are supported overlapping each other in a cantilever fashion which would allow elimination of the elevators 72, 84.
Referring to
The tab 130 on a side 136 has a piezoelectric actuator 140. The tab 134 on a side 142 has a piezoelectric actuator 144. If desired piezoelectric actuators 140, 144 can be placed upon opposite sides of their respective tabs or within their respective substrates 128, 142. As shown, the tabs 130, 134 are in their first non-actuated, spaced away position and activation of the piezoelectric circuits causes the tabs 130, 134 to be actuated and placed toward one another causing contact between first and second conductive members which are etched or printed on sides 146, 148 of the tabs. The relay arrangement 127 can be:. configured to be normally opened upon non-activation or to be normally closed upon: activation. The other logic options as previously discussed in regards to relay arrangement 67 are also available.
While preferred embodiments of the present invention have been disclosed, it is to be understood that they have been disclosed by way of example only and that various modifications can be made without departing from the spirit and scope of the invention. as it is encompassed by the following claims.
Claims
1-27. (canceled).
28. An arrangement of a flex circuit relay comprising:
- a first substrate;
- a first conductive member connected on said first substrate;
- a second flexible substrate having a contact portion in a first position spaced away from said first substrate and said contact portion in a second position being spaced adjacent to said first substrate;
- a second conductive member connected on said second substrate for making contact with said first conductive member; and
- a piezoelectric film actuator connected with said second substrate to cause said second substrate contact portion to move between said first and second positions.
29. An arrangement of a flex circuit relay as described in claim 28, wherein when said actuator is non-excited, said contact portion of said second substrate is in said first position.
30. An arrangement of a flex circuit relay as described in claim 28, wherein when said actuator is excited, said contact portion of said second substrate is in said second position.
31. An arrangement of a flex circuit relay as described in claim 28, wherein said first substrate is rigid.
32. An arrangement of a flex circuit relay as described in claim 28 wherein said second substrate is cantileverly supported on said first substrate.
33. An arrangement of a flex circuit relay as described in claim 32, wherein said second substrate is supported on a conductive elevator located on said first substrate.
34. An arrangement of a flex circuit relay as described in claim 33, wherein said elevator is a surface mounted device.
35. An arrangement of a flex circuit relay as described in claim 28, wherein one of said conductive members is a surface mounted device.
36. An arrangement of a flex circuit relay as described in claim 28, wherein said actuator is on a side of said second substrate generally opposite said first substrate.
37. An arrangement of a flex circuit relay wherein said actuator is on a side of said second substrate adjacent to said first substrate.
38. An arrangement of a flex circuit relay as described in claim 28, having multiple film piezoelectric actuators.
39. An arrangement of a flex circuit relay as described in claim 28, wherein said second substrate is supported as a beam and bows to move between said first and second positions.
40. An arrangement of a flex circuit relay as described in claim 28, wherein said first substrate is a flexible substrate.
41. An arrangement of a flex circuit relay as described in claim 28, wherein there is a third conductive member on one of said first and second substrates gapped from one of said first and second conductive members and wherein said other one of said first and second conductive member electrically connects said third conductive member with said one of said first and second conductive members.
42. An arrangement of a flex circuit relay as described in claim 41, wherein said third conductive member is gapped from said first conductive member on said first substrate and wherein said second conductive member electrically connects said first and third conductive members.
43. An arrangement of a flex circuit relay as described in claim 28, wherein said relay forms a conductive circuit between said second conductive member and said first conductive member.
44. An arrangement of a flex circuit relay as described in claim 40, wherein said first substrate has an actuator for moving a contact portion of said first substrate between a first position spaced away from said second substrate contact portion and a second position being spaced adjacent to said second substrate contact portion.
45. An arrangement of a flex circuit relay comprising:
- a first substrate;
- a pair of conductive members gapped from one another connected on said first substrate;
- a conductive elevator connected on said first substrate;
- a second flexible substrate having one end cantileverly supported on said elevator, said second flexible substrate having a contact portion in a first position spaced away from said first substrate and said contact portion in a second position being spaced adjacent to said first substrate for making contact with said pair of said conductive members on said first substrate; and
- a piezoelectric actuator connected on said second substrate to cause said second surface substrate contact portion to move between said first and second positions.
46. An arrangements of a flex circuit relay comprising:
- a pair of conductive members connected on said first substrate having a gap there between;
- two conductive elevators connected on said first substrate;
- a second flexible substrate supported in on a beam like manner from said first and second elevators, said second substrate having a contact portion in a first position spaced away from said first substrate and said contact portion in a second position being spaced adjacent to said first substrate;
- a second conductive member connected on said second substrate for making electrical connection between said pair of conductive members on said first substrate; and
- a film piezoelectric actuator connected with said second substrate to cause said second substrate contact portion to move between said first and second positions.
47. An arrangement of a flex circuit relay a first flexible substrate cantileverly supported;
- a first conductive member connected on said first substrate;
- a second flexible substrate cantileverly supported;
- a second conductive member connected on a said second substrate;
- a first film piezoelectric actuator for moving said first flexible substrate between a first position spacing said first conductive member away from said second conductive member and a second position placing said first conductive member adjacent to said second conductive member; and
- a second film piezoelectric actuator connected on said second substrate to cause said second substrate to move said second conductive member from a first position spaced away from said first conductive member and a second position wherein said second conductive member is spaced adjacent to said first conductive member.
48. An arrangement of a flex circuit relay comprising:
- a first flexible substrate having a first integral tab portion;
- a first conductive member connected on said first substrate tab portion;
- a second flexible substrate having a second integral tab portion;
- a second conductive member connected on said second substrate second tab portion;
- a first piezoelectric actuator for moving said first substrate tab portion between a first position spacing said first conductive member away from said second conductive member and a second position placing said first conductive member adjacent to said second conductive member; and
- a second piezoelectric actuator for moving said second substrate tab portion between a first position spaced away from said first conductive member and a second position placing said second conductive member adjacent to said first conductive member.
49. An arrangement of a flex circuit relay as described in claim 40, wherein said first and second substrates are formed from a continuous member.
50. A method of electrically connecting two circuit devices comprising:
- connecting on a first substrate a first conductive member;
- connecting on a second flexible substrate a second conductive member and spacing said second flexible substrate in a first position spaced away from said first substrate and spacing said second flexible substrate in a second position being spaced adjacent to said first substrate; and
- piezoelectrically actuating said second substrate between said first and second positions utilizing a film piezoelectric actuator.
51. A method of electrically connecting two circuit devices as described in claim 50, further comprising:
- connecting a third conductive member on one of said first and second substrates gapped from one of said first and second conductive members and wherein said other one of said first and second conductive members electrically connects said third conductive member with said one of said first and second conductive members.
52. A method of electrically connecting two circuit devices as described in claim 50, further comprising forming a conductive circuit between said second conductive member and said first conductive member.
Type: Application
Filed: Jul 26, 2004
Publication Date: Mar 17, 2005
Inventors: Thomas Belanger (Saline, MI), David Rutkowski (Grosse Ile, MI)
Application Number: 10/899,256