Source: http://www.google.com/patents/US5623102?dq=6,970,917
Timestamp: 2015-01-27 04:16:32
Document Index: 451309442

Matched Legal Cases: ['art 3', 'art 4', 'art 3', 'art 4', 'arts 3', 'arts 3', 'arts 3']

Patent US5623102 - Three wafer semiconductor pressure-difference sensor and method for ... - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsA pressure difference sensor having a semiconductor measuring diaphragm clamped between two bearing parts of insulating material thereby forming two inner chambers is described. Each of the bearing parts holds a flat electrode on its inside. An internal, pressurized, equalization chamber is provided...http://www.google.com/patents/US5623102?utm_source=gb-gplus-sharePatent US5623102 - Three wafer semiconductor pressure-difference sensor and method for manufacture separating middle wafer into conducting diaphragm and webAdvanced Patent SearchPublication numberUS5623102 APublication typeGrantApplication numberUS 08/295,692PCT numberPCT/DE1993/000166Publication dateApr 22, 1997Filing dateOct 22, 1992Priority dateFeb 28, 1992Fee statusPaidAlso published asDE4206675A1, DE4206675C2, EP0628160A1, EP0628160B1, WO1993017313A1Publication number08295692, 295692, PCT/1993/166, PCT/DE/1993/000166, PCT/DE/1993/00166, PCT/DE/93/000166, PCT/DE/93/00166, PCT/DE1993/000166, PCT/DE1993/00166, PCT/DE1993000166, PCT/DE199300166, PCT/DE93/000166, PCT/DE93/00166, PCT/DE93000166, PCT/DE9300166, US 5623102 A, US 5623102A, US-A-5623102, US5623102 A, US5623102AInventorsFrank Arndt, Detlef Houdeau, Moritz von Rauch, Helmut SchlaakOriginal AssigneeSiemens AktiengesellschaftExport CitationBiBTeX, EndNote, RefManPatent Citations (11), Referenced by (7), Classifications (12), Legal Events (4) External Links: USPTO, USPTO Assignment, EspacenetThree wafer semiconductor pressure-difference sensor and method for manufacture separating middle wafer into conducting diaphragm and webUS 5623102 AAbstract A pressure difference sensor having a semiconductor measuring diaphragm clamped between two bearing parts of insulating material thereby forming two inner chambers is described. Each of the bearing parts holds a flat electrode on its inside. An internal, pressurized, equalization chamber is provided in the clamping region of the pressure difference sensor and extends into both bearing parts around the inner chambers. The equalization chamber compensates for static pressure influences on the accuracy of the measurement of the sensor. A method for producing the sensor is also described.
We claim: 1. A method for the manufacture of pressure-difference sensors having a semiconductor measuring diaphragm which is clamped between two bearing parts so that two inner chambers are formed for each pressure-difference sensor, each chamber being defined by the diaphragm and a bearing part, each of the bearing parts holding a flat electrode on its inside, one inner chamber being adapted to be acted on, via a passage opening in one bearing part, by a first pressure of a pressure-difference to be measured and the other inner chamber adapted to be acted on by a second pressure of the pressure difference to be measured, the semiconductor measuring diaphragm being connected with an outer connector and the flat electrodes being connected with outer connectors to produce the pressure-difference sensors having external connectors on a free surface of a bearing part, the method comprising the steps of:bonding a first wafer having several bearing parts, to a second wafer having a plurality of semiconductor measuring diaphragms, a rectangular passage hole being present in each case on one side of the semiconductor measuring diaphragm, wherein each bearing part of the first wafer has an outer connector for the semiconductor measuring diagram and outer connectors for the electrodes for each pressure-difference sensor, each connector being disposed on a free surface of the first wafer defined by the rectangular passage hole of the second wafer; partially cutting through said second wafer from the rectangular passage hole at an acute angle to its lengthwise direction thereby electrically insulating a web of the second wafer lying adjacent to the rectangular passage hole, from the semiconductor measuring diaphragm; bonding a third wafer to the second wafer each third wafer having a plurality of further bearing parts, and each bearing part provided with a flat electrode having a conductive path so that an electrical connection occurs from each electrode in the third wafer via the conductive path and the web to the outer connector; and making separating cuts through the rectangular passage holes, in their lengthwise direction and perpendicular thereto, thereby forming the pressure-difference sensors. 2. The method according to claim 1 wherein an inner pressurized equalization space is provided in a region where the bearing parts clamp the semiconductor measuring diaphragm, the equalization space extends into both bearing parts and around the inner chambers.
7. A method for the manufacture of pressure-difference sensors, each having a semiconductor measuring diaphragm clamped between two bearing parts so that two inner chambers are formed, each chamber defined by the diaphragm and a bearing part, each of the bearing parts holding a flat electrode on its inside, a first inner chamber being adapted to be acted on, via a passage opening in a first bearing part, by a first pressure of the pressure-difference to be measured, a second inner chamber adapted to be acted on by a second pressure of the pressure-difference to be measured, the semiconductor measuring diaphragm and the flat electrodes being connected with outer connectors, the method comprising steps of:a) providing several bearing parts of a first wafer, each bearing part having a flat electrode, and each flat electrode having an external connector on a free surface of a bearing part; b) bonding a second wafer having a plurality of semiconductor measuring diaphragms, to the first wafer, wherein a rectangular passage hole is present on one side of each of the semiconductor measuring diaphragms; c) electrically insulating a web of the second wafer, lying adjacent to the rectangular passage hole, from the semiconductor measuring diaphragms by partial cuts through the second wafer which extend from the rectangular passage hole at an acute angle to its lengthwise direction; d) providing each of a plurality of further bearing parts of a third wafer with a flat electrode, each flat electrode having an outer connector; e) bonding the third wafer to the second wafer; and f) forming the pressure-difference sensors by separating cuts through the rectangular passage holes in their lengthwise direction and perpendicular thereto. 8. The method according to claim 7 wherein, in the region where the bearing parts clamp the semiconductor measuring diaphragm, there is an inner pressurized equalization space which extends into both bearing parts and around the inner chambers.
9. The method according to claim 8 further comprising a step of:sealing off the equalization space from the inner chambers and permitting the equalization space to be acted on by the first or second pressure via an opening which extends to the outside of the sensor. 10. The method according to claim 8 further comprising a step of:connecting the equalization space, in pressure-transmitting manner, with one of the inner chambers. 11. The method according to claim 8 further comprising a step of:dividing the equalization space into a plurality of equalization chambers which are arranged around the inner chambers. 12. The method according to claim 8 further comprising steps of:connecting, in a pressure-transmitting manner, an equalization chamber with a filling opening for a non-compressible liquid and with an inner chamber; and connecting, in pressure-transmitting manner, a further equalization chamber with a further filling opening for a non-compressible liquid and with an other inner chamber. 13. A pressure-difference sensor comprising:a) a semiconductor measuring diaphragm having a peripheral region; b) a lower bearing part having a first side and a second side, said first side of said lower bearing part having a recessed region having a first thickness and having plateau regions on either side of the recessed region, the plateau regions having a second thickness greater than said first thickness, wherein said peripheral region of said semiconductor measuring diaphragm is bonded, in an electrically insulating manner, to a portion of said plateau regions of said lower bearing part thereby defining a first inner chamber and wherein a portion of the first side of the lower bearing part is a free surface; c) an upper bearing part having a first side and a second side, said first side of said upper bearing part having a recessed region having a third thickness and having plateau regions on either side of the recessed region of the upper bearing part, the plateau regions of the upper bearing part having a fourth thickness greater than said third thickness, wherein said peripheral region of said semiconductor measuring diaphragm is bonded, in an electrically insulating manner, to said plateau regions of said upper bearing part thereby defining a second inner chamber; d) a first equalization chamber formed in at least one of the upper and lower bearing parts; e) a second equalization chamber formed in at least one of the upper and lower bearing parts; f) a first channel fluidly coupling said first equalization chamber with said first inner chamber; g) a second channel fluidly coupling said second equalization chamber with said second inner chamber; h) a first electrode arranged on said recessed region of said lower bearing part; i) second electrode arranged on said recessed region of said upper bearing part; j) a first outer connector arranged on said free surface of the first side of said lower bearing part; k) a second outer connector arranged on said free surface of the first side of said lower bearing part; l) a first conductive path electrically coupling said first electrode with said first outer connector; m) a second conductive path electrically coupling said second electrode with said second outer connector, wherein said second conductive path includes a web adjacent to, and insulated from, said semiconductor measuring diaphragm; n) a third outer connector arranged on said free surface of the first side of said lower bearing part; and o) a third conductive path electrically coupling said semiconductor measuring diaphragm with said third outer connector. Description
BACKGROUND OF THE INVENTION The present invention is related to a method for manufacturing pressure-difference sensors having a semiconductor measurement diaphragm clamped between two bearing parts.
SUMMARY OF THE INVENTION To achieve the aforementioned object, the present invention provides a method for the manufacture of pressure-difference sensors having a semiconductor measuring diaphragm clamped between two bearing parts thereby forming an inner chamber in each case. Each of the bearing parts holds a flat electrode on an inside surface. A first inner chamber is adapted to be acted on, via a passage opening in a first bearing part, by a first pressure of the pressure difference to be measured. A second inner chamber is adapted to be acted on by a second pressure of the pressure difference to be measured. The semiconductor measuring diaphragm and the flat electrodes are electrically connected with external connectors.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a section through an embodiment of the pressure-difference sensor of the present invention along the cut I--I of FIG. 2.
DETAILED DESCRIPTION The pressure-difference sensor 1 shown in FIG. 1 has a semiconductor measuring diaphragm 2. The measuring diaphragm 2 is preferably made of silicon which is doped so that it is sufficiently conductive. The semiconductor measuring diaphragm 2 is clamped between an upper bearing part 3 and a lower bearing part 4. Both the upper bearing part 3 and the lower bearing part 4 preferably consist of semiconductor material such as silicon. The region 5 of the semiconductor measuring diaphragm 2 is bonded to the two bearing parts 3 and 4 thereby firmly clamping the measuring diaphragm 2. Bondable glass layers (not shown in the figure) are present between the semiconductor measuring diaphragm 2 and the bearing parts 3 and 4 to insulate them. However, the bearing parts 3 and 4 may also consist of glass or ceramics.
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