PRESSURE SENSING MODULE HAVING AN INTEGRATED SEAL PLATE AND
METHOD OF ASSEMBLING PRESSURE SENSING MODULE
CROSS-REFERENCE TO RELATED APPLICATIONS
This application claims the benefit of United States Patent Application
12/267,889, filed November 10, 2008, which is hereby incorporated by reference in its
entirety.
TECHNICAL FIELD
This disclosure relates to a pressure sensing module for sensing the
pressure of fluid pressure sources.
BACKGROUND OF THE INVENTION
Transmission systems are one example of common hydraulic fluid
applications. Fluid pressure (of a liquid or gas) is one element that is monitored to
measure performance and to operate such systems.
In an automotive automatic transmission system, for example, electronic
controls are commonly used to control the pressure of the hydraulic fluid within the fluid
lines. By varying the pressure of the hydraulic fluid in the lines, various elements of the
automatic transmission system, including the engagement of individual clutches, may be
controlled. For example, by varying the pressure of the hydraulic fluid in the fluid lines,
the shift points of the gears may be controlled.
SUMMARY
A method of assembling a pressure sensing module includes placing a
pressure sensor unit on an alignment tool and indexing the alignment tool to a circuit
board. The pressure sensor unit may be attached to the circuit board and the alignment
tool removed from the pressure sensor unit. A seal plate is indexed to the circuit board
and the pressure sensor to form a fluid seal between the pressure sensor unit and seal
plate.
An integrated seal module for sealing one or more pressure ports to one or
more pressure sources is further provided. The seal module includes a mounting plate
having a first surface and a second surface on opposing sides thereof, and at least one
locator hole defined by the mounting plate and extending through the mounting plate
between the first and second surfaces. One or more pressure passages are defined by the
mounting plate and extend therethrough between the first and second surfaces. A unitary
seal member is configured to effect a fluid seal between the one or more pressure ports
and the first face, and configured to effect a fluid seal between the one or more pressure
sources and the second face.
The above features and advantages and other features and advantages of
the present invention are readily apparent from the following detailed description of the
best modes and other embodiments for carrying out the invention when taken in
connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a schematic perspective view of an integrated seal module
incorporated into a pressure sensing module shown against a valve or manifold (shown in
phantom) having pressure sources therein;
Figure 2 is a schematic, cross-sectional, perspective view of the integrated
seal module and pressure sensors shown in Figure 1, shown with one pressure sensor
removed for illustrative purposes;
Figure 3 is a schematic, perspective, exploded view of an alignment tool
or fixture and a sensor array which may be used to assemble a pressure sensing module
such as that shown in Figure 1; and
Figure 4 is a schematic, cross-sectional, perspective view of an
overmolded integrated seal module, shown with a portion of one pressure sensor and
associated overmolding removed for illustrative purposes.
DESCRIPTION OF PREFERRED EMBODIMENTS
Referring to the drawings, wherein like reference numbers correspond to
like or similar components throughout the several figures, there is shown in Figure 1 an
exemplary embodiment of an integrated seal module 10 for sealing a valve body or
manifold 12 (shown in phantom) to a sensor array 14. For illustrative purposes, the
manifold 12 is shown in phantom to better view the integrated seal module 10. Those
having ordinary skill in the art will recognize that terms such as "above," "below,"
"upward," "downward," et cetera, are used descriptively of the figures, and do not
represent limitations on the scope of the invention, as defined by the appended claims.
Manifold 12 is shown only partially in Figure 1, and may be part of
transmission, brake, or other automotive systems. Alternatively, manifold 12 may be part
of non-automotive systems, such as industrial and manufacturing systems having
controlled or monitored fluid systems. The pressure in manifold 12 is monitored to assist
in accurate and repeatable control of the fluid system. Sensor array 14 and integrated seal
module 10 combine to form a pressure sensing module 15 that can accurately measure
multiple sources of pressure from the manifold 12.
In the embodiment shown in Figure 1, there are six pressure sources 16,
17, 18, 19, 20, and 21, each communicating with a manifold face 22 via one respective
line 24. Each pressure source 16-21 may be separately monitored by measuring the
pressure in a respective one of the lines 24. The manifold 12 shown in Figure 1 has the
lines 24 arranged in three pairs, corresponding to pairs of pressure sources 16, 17; 18, 19;
and 20, 21. Those having ordinary skill in the art will recognize that the number,
configuration, and spacing of pressure sources 16-21 and lines 24 need not be limited to
the embodiment shown in Figure 1.
The sensor array 14 includes a circuit board 28 having three sensors 30
mounted thereon. In the embodiment shown, each of the three sensors 30 is a small
outline integrated circuit (SOIC). Those having ordinary skill in the art will recognize
other sensors that may be arranged to measure pressure in the lines 24, and will further
recognize fewer or additional sensors 30 may be utilized within the scope of the
appended claims.
Sensors 30 communicate electronically with the circuit board 28 via pins
32, which carry signals indicative of the pressure measured by the sensors 30 (as
described in more detail below). Pins 32 contact terminals 34 on the circuit board 28, and
may be connected by a soldering process. The solder medium (not shown) acts both to
bind the pins 32 to respective terminals 34 and to facilitate electrical communication
therebetween.
Circuit board 28 further includes one or more alignment holes 26 (blocked
from view by mounting plate 40 in Figure 1, shown in Figure 3), which are located in
fixed positions on the circuit board 28. The alignment holes 26 therefore provide an
indexing feature allowing the features of the circuit board 28 - such as the terminals 34 -
to be located relative to the alignment holes 26.
The integrated seal module 10 is disposed generally between the manifold
12 and sensory array 14, and includes a seal plate or mounting plate 40. On opposing
faces of the mounting plate 40 are a first surface 42 and a second surface 44. In the
embodiment shown in Figure 1, the first surface 42 faces the sensor array 14 and the
second surface 44 faces the manifold 12.
Integrated seal module 10 further includes one or more locator holes 46
connecting and extending between the first and second surfaces 42 and 44. Locator holes
46 act as indexing receptacles, which are configured to locate, key, or align the integrated
seal module 10 relative to the sensor array 14.
One or more indexing posts 48 may be affixed to, or formed as part of, the
manifold 12, thereby providing fixed reference features from the manifold 12 for the
sensor array 14 and seal module 10. Indexing posts 48 are shown in phantom in Figure 1,
and are configured to extend through the seal module 10 and the circuit board 28. The
indexing posts 48 act as indexing features and interact with the locator holes 46 (indexing
receptacles) to index the integrated seal module 10 relative to the manifold 12.
Indexing posts 48 are further configured to interact with the alignment
holes 26 of the circuit board 28. Therefore, by indexing the locator holes 46 to the
indexing posts 48, and by indexing the alignment holes 26 to the indexing posts 48; the
integrated seal module 10, circuit board 28, and manifold 12 may all be located and
aligned with predetermined respective spatial relationships. The alignment holes 26 and
locator holes 46 are shaped to closely match the profile of the indexing posts 48.
Optionally, as shown in Figure 1, the each of the alignment holes 26 and
locator holes 46 may be shaped differently to key the mating of the integrated seal
module 10 with the manifold 12 and the sensor array 14, Those having ordinary skill in
the art will recognize other indexing features and elements which may be used to align
and locate the integrated seal module 10 relative to the sensor array 14 and/or the
integrated seal module 10 relative to the manifold 12.
The integrated seal module 10 includes one or more bushings 50 (two, in
the embodiment shown in Figure 1) disposed within the locator holes 46. Bushings 50
facilitate mating of the locator holes 46 to the indexing posts 48, such that the interior
surfaces of the bushings 50 act as indexing receptacles. Furthermore, the bushings 50
compensate for slight misalignment of the locator holes 46 relative to the indexing posts
48 by providing a pliable or adaptable interface therebetween.
As shown in Figure 1, six pressure passages 52 are defined by the
mounting plate 40 and extend between the first and second surfaces 42 and 44. The
pressure passages 52 are generally coaxial with the lines 24 at the manifold face 22, and
are configured to provide fluid communication between the pressure sources 16-21 and
pressure ports 53 on the sensors 30.
Depending upon the configuration of the sensor array 14 and the sensors
30, each of the sensors 30 may monitor and measure one or more of the pressure sources
16-21. In the embodiment shown in Figure 1, there are three sensors 30, each measuring a
pair of the pressure sources 16-21. Pressure ports 53 on the pressure sensors 30 (blocked
from view in Figure 1, shown in Figure 4) measure the pressure of the pressure sources
16-21. The number of pressure ports 53 on each pressure sensor 30 determines the
number of individual pressure sources which can be measured by each pressure sensor 30
and, therefore, by the sensor array 14. Each pressure sensor 30 may have one or more
pressure ports 53.
To prevent leakage of fluids and subsequent false readings of the pressure
in pressure sources 16-21, the integrated seal module 10 includes sealing elements 54 at
each of the interfaces between the lines 24, pressure passages 52, and the pressure ports
53 on sensors 30. In the embodiment shown in Figure 1, there are six sealing elements 54
on each of the first and second surfaces 42 and 44. AH twelve of the sealing elements 54
and both of the bushings 50 are formed together as a continuous, unitary seal member 56.
The circuit board 28, or some other element of the sensor array 14, may be
configured to receive mounting hardware (not shown) which attaches the sensor array 14
and the integrated seal module 10 to the manifold 12. The mounting hardware also
provides force to compress the sealing elements 54 between the sensors 30 and the first
surface 42 of the integrated seal module 10 and between the manifold 12 and the second
surface 44.
In an alternative embodiment (not shown), the indexing posts 48 may be
formed as separate elements from the manifold 12. In such an embodiment, the indexing
posts 48 may be configured with integrated mounting hardware or features. Therefore, in
addition to indexing the sensor array 14 to the integrated seal module 10 and the manifold
12, the indexing posts 48 would also attach or affix the sensor array 14 and integrated
seal module 10 to the manifold 12.
Referring now to Figure 1, and also to Figure 2, which is an alternative
view of the integrated seal module 10 shown in Figure 1. Figure 2 shows a cross-
sectional view of the integrated seal module 10 and two of the pressure sensors 30. The
third pressure sensor 30 has been removed from Figure 2 to show one of the sealing
elements 54 on the first surface 42.
Unitary seal member 56 includes sealing elements 54 on both sides of
mounting plate 40, and has connecting portions 58 which pass between the first and
second surfaces 42 and 44. As shown in Figure 2, the connecting portions 58 are
completely surrounded and encased by the material of mounting plate 40.
The unitary seal member 56 may be formed from liquid injection molded
(LIM) silicon or another suitable material. The LIM silicon is molded into preformed
channels and grooves in the mounting plate 40, thereby forming the sealing elements 54,
bushings 50, and connecting portions 58.
The unitary seal member 56 incorporates multiple sealing elements 54 and
therefore replaces multiple seals, such as small o-rings. Removal of multiple seals
reduces the difficulty, time, and cost of manufacturing the pressure sensing module 15.
Furthermore, the unitary seal member 56 reduces the possibility of inter-seal leakage
which may cause fluid flow between the lines 24 and result in mixing of the pressure
sources 16-21.
Manufactured products are subject to variation. Tolerances limit the
variation allowed for individual feature geometry, such as form and size, and limit the
geometric relationship between features, such as orientation and location. The cumulative
effects of the tolerances - known as "stackups" - may result in structures or assemblies
that are unacceptable.
In general terms, pressure sensing devices need to provide both a robust
seal and sufficient fluid communication between the pressure sources (such as 16-21) and
the pressure measurement devices (such as the pressure ports 53). However, variance
stackups may inhibit fluid communication between the pressure sources (16-21) and the
pressure measurement locations (53) by offsetting the fluid channels (lines 24 and
pressure passages 52).
As shown in Figure 1 and 2, to achieve a reasonably accurate pressure
measurement from the pressure sensing module 15, the pressure ports 53 on the pressure
sensors 30 need to fluidly communicate with the pressure sources 16-21. Accurate
measurements require robust seals between the lines 24 and the pressure passages 52, and
also require robust seals between the pressure passages 52 and the pressure sensors 30.
In the integrated seal module 10, incorporation of the sealing elements 54
on both the first and second surfaces 42 and 44 reduces the effects of the accumulated
variations that occur due to manufacture and installation tolerances of separate seals. By
reducing the number of parts used to seal the interfaces between the pressure sources 16-
21 and the sensors 30, the tolerance stackups are similarly reduced.
Another embodiment of the integrated seal module 10 may include cradles
or brackets (not shown). The cradles or brackets are configured to engage or lock onto the
sensors 30, and may assist in aligning the pressure passages 52 with the pressure ports 53
on the sensors 30. For example, the cradles may be configured to lock onto the comers of
the pressure sensors 30, which may assist in holding and aligning the pressure sensors 30
relative to the circuit board 28 prior to soldering the pins 32 to the terminals 34.
Referring now to Figure 3, there is shown a perspective, exploded view of
the sensor array 14 shown in Figure 1, along with a frame or alignment tool 100. The
alignment tool 100 may be used to decrease alignment errors during assembly of the
pressure sensing module 15 shown in Figure 1.
Alignment tool 100 contains structure configured to properly locate and
align the pressure sensors 30 on the circuit board 28 of sensor array 14. In the
embodiment shown in Figure 3, up to three pressure sensors 30 may be temporarily
affixed to, or placed in, corresponding brackets 102 on the alignment tool 100. The
brackets 102 may be shaped with an outline generally matching that of the pressure
sensors 30. Brackets 102 hold and properly locate the pressure sensors 30 relative to the
circuit board 28 and relative to each other (where more than one pressure sensor 30 is
used in the sensor array 14).
One or more locator holes 146 are defined by the alignment tool 100.
Locator holes 146 are similar to the locator holes 46 on the integrated seal module 10 and
index the alignment tool 100 relative to the circuit board 28. The locator holes 146 are
configured to mate with one or more indexing posts 148, which are similar in
configuration to indexing posts 48 (although shown coming from a different direction).
Indexing posts 148 may be attachable to the circuit board 28, free-standing, or attached to
an additional fixture or hard tooling. The indexing posts 148 are also configured to mate
with the alignment holes 26 of circuit board 28.
In an alternative embodiment (not shown), the indexing posts 148 may be
formed as an integral part of the alignment tool 100. Such an embodiment would
eliminate the locator holes 146, as the indexing posts 148 would already be located
relative to the alignment tool 100.
In the embodiment shown, the brackets 102 are tapered, which allows the
brackets 102 to both vertically and horizontally align the pressure sensors 30 in the
alignment tool 100. By affixing the pressure sensors 30 to the alignment tool 100 and
sliding the locator holes 146 over the indexing posts 148, each of the pressure sensors 30
may be indexed and located relative to the circuit board 28.
In operation, the pressure sensors 30 may be affixed to the brackets 102 in
one location of the manufacturing facility and then moved to the circuit board 28 at
another location. Movement and rotation of the alignment tool 100 and pressure sensors
30 may be accomplished by grabbing a pair of tabs 106 on opposing ends of the
alignment tool 100. Robotics or manual labor may be employed to move and rotate the
alignment tool 100 and to index the alignment tool 100 to the circuit board 28.
In order to temporarily affix the pressure sensors 30 to the brackets 102,
the alignment tool 100 may include structure to grab and hold the pressure sensors 30.
For example, rubber gaskets (not shown) may partially overlap portions of the brackets
102, such that the pressure sensors 30 are grabbed by the rubber gaskets when pressed
into the brackets 102.
After the pressure sensors 30 have been properly located relative to the
circuit board 28, the pins 32 may be soldered or otherwise attached to the terminals 34.
The pressure sensors 30 are now attached to the circuit board 28 and the alignment tool
100 may be removed, leaving the assembled sensor array 14 behind, ready to be installed
into the pressure sensing module 15. In embodiments where rubber gaskets are used to
hold the pressure sensors 30 to the brackets 102, the rubber gaskets are configured to
grasp the pressure sensors 30 with less force than the attachment force of the solder
holding the pins 32 to the terminals 34.
Further embodiments of the alignment tool 100 may include other
structures for temporarily holding the pressure sensors 30 against the brackets 102 during
movement of the alignment tool 100 and also during the soldering stage. The alignment
tool may be equipped with clips (not shown) capable of locking the pressure sensors 30
to the brackets 102. Additionally, temporary adhesives may be used to retain the pressure
sensors 30. Furthermore, a vacuum may be included on the alignment tool 100 to hold the
pressure sensors 30 until the pins 32 have been soldered to the terminals 34.
Soldering the pins 32 to the terminals 34 creates a liquid layer between
individual pins 32 and terminals 34 as the solder medium melts. The liquid layer may
cause the pressure sensors 30 to float, which may cause the pressure sensors 30 to slide
and rotate until the solder cools, resulting in possible misalignment of the pressure
sensors 30 relative to the circuit board 28.
Possible misalignment of the pressure sensors 30, due to movement during
the soldering process, increases the variance stackups of the pressure sensing module 15
that can be assembled from the sensor array 14. By using the alignment tool 100 to hold
the pressure sensors 30 during the soldering process, the pressure sensors 30 may be
restrained from floating, and are therefore aligned with increased accuracy relative to the
circuit board 28.
The (properly-aligned) sensor array 14 may then be joined to the
integrated seal module 10 or another sealing plate to form the pressure sensing module
15. The indexing features on the integrated seal module 10 and the alignment tool 100 are
configured to provide highly-accurate alignment of the pressure passages 52 with the
pressure ports 53 on the pressure sensors 30 and also with the lines 24 of the manifold 12.
As described above, and referring again to Figures 1 and 3, alignment tool
100 may be used with a method of assembling a pressure sensing module. For illustrative
purposes, the method is described with reference to the alignment tool 100 and the
pressure sensing module 15, However, those having ordinary skill in the art will
recognize that the method, as described in the claims, may be executed with other
structure.
The method includes affixing a pressure sensor unit to the alignment tool
100. The pressure sensor unit may be similar to the sensor array 14, and may include one
or more pressure sensors 30, which are aligned by the alignment tool 100 into a pattern or
configuration matching the desired pattern or configuration of the pressure sensors 30 in
the pressure sensing module 15. The pressure sensors 30 may be affixed to the alignment
tool 100 by temporary adhesives, vacuum devices, gaskets, or other structure configured
to temporarily hold the pressure sensors 30 to the brackets 102.
The alignment tool 100 and aligned pressure sensor unit are then moved in
tandem to the circuit board 28, where the alignment tool 100 is indexed to the circuit
board 28. Indexing may occur through one or more locator features, such as the indexing
posts 148, being aligned with one or more receptacle elements on the alignment tool 100,
such as the locator holes 146.
After indexing the alignment tool 100 to the circuit board 28 - and
therefore aligning and locating each of the one or more pressure sensors 30 in the
pressure sensor unit to the circuit board 28 - the pressure sensor unit is attached to the
circuit board 28. The pressure sensors 30 may be attached to the circuit board by
soldering the pins 32 to the terminals 34 or by physically capturing the pins 32 such that
the pressure sensors 30 communicate with the circuit board 28.
The alignment tool 100 is then removed from the pressure sensor unit,
leaving the one or more pressure sensors 30 or the pressure sensor unit solidly affixed to
the circuit board 28. A seal plate, such as the integrated seal module 10, is then indexed
to the circuit board 28. The seal plate is attached such that the seal plate covers the
pressure sensor unit to form a fluid seal between the pressure sensor unit and the seal
plate.
The fully-assembled pressure sensing module 15 may then be attached to
the manifold 12 or another device having pressure sources to be measured by the pressure
sensing module 15. As shown in Figures 1 and 3, the method may include attaching a
pressure sensor unit which has a pattern or array of at least three pressure sensors 30.
A further method of assembling a pressure sensing module (similar to the
pressure sensing module 15 shown in Figure 1) includes using a modified integrated seal
module (not shown) as an alignment tool. In such a method, the modified integrated seal
module would include a cradling mounting plate (not shown) having cradles, brackets, or
other structure (not shown) configured to grasp the pressure sensors 30. The cradles are
configured to index the pressure sensors 30 relative to the pressure passages 52 of the
cradling mounting plate.
This additional method uses the modified integrated seal module as the
alignment tool by affixing the pressure sensors 30 to the cradles on the cradling mounting
plate, and then indexing the modified integrated seal module and pressure sensors 30 to
the circuit board 28. In such an embodiment, the modified integrated seal module is
configured to withstand the heat of the soldering process, such that the pressure sensors
30 may be soldered to the circuit board 28 while already attached to the modified
integrated seal module. This method relieves the assembly process of the need to
separately align the pressure sensors 30 to the pressure passages 52, and therefore
removes the accompanying variance.
Referring now to Figure 4, there is shown a partial, cross-sectional view of
a further embodiment of an integrated seal module: an overmolded seal module 210,
which includes pressure sensors 30 overmoided in the material of a mounting plate 240.
In the overmoided seal module 210, the mounting plate 240 is formed in a mold (not
shown) in which the pressure sensors 30 have been placed and properly aligned.
Overmoided portions 260 extend from a first face 242 to at least partially
encase the pressure sensors 30. The pins 32 however, are not completely overmoided and
may still be soldered or otherwise attached to the circuit board 34. Pressure passages 52
formed in the mounting plate 240 directly connect the lines 24 of the manifold 12 with
pressure ports 53 on the pressure sensors 30, such that no sealing elements are required
between the pressure sensors 30 and the pressure passages 52. Note that in the view
shown in Figure 4, a portion of one of the pressure sensors 30 and overmolded portions
260 has been removed to show one pressure passage 52 and the corresponding pressure
port 53.
The overmolded seal module 210 includes a continuous seal member 256,
which is liquid injection molded into the mounting plate 240. However, unlike the unitary
seal member 56 shown in Figures 1 and 2, the continuous seal member 256 of the
overmolded embodiment only includes seal elements 254 between the pressure passages
52 and the lines 24 of the manifold 12. The continuous seal member 256 of the
overmolded embodiment also includes bushings 250 around locator holes, similar to
those shown on the integrated seal module 10 in Figure 1.
During the assembly process, the pressure sensors 30 and mounting plate
240 are formed together. The continuous seal member 256 may then be liquid injection
molded to complete the overmolded seal module 210, with pressure sensors 30 already
attached and properly located and aligned relative to the pressure passages 52, The
overmolded seal module 210 may then be indexed to the circuit board 28 and the pins 32
soldered to the terminals 34.
While the best modes and other embodiments for carrying out the claimed
invention have been described in detail, those familiar with the art to which this invention
relates will recognize various alternative designs and embodiments for practicing the
invention within the scope of the appended claims.
We claim:
1. A method of assembling a pressure sensing module (15),
comprising:
placing a pressure sensor unit (30) on an alignment tool (100);
indexing the alignment tool (100) to a circuit board (28);
attaching the pressure sensor unit (30) to the circuit board (28),
removing the alignment tool (100) from the pressure sensor unit
(30);
indexing a seal plate (40) to the circuit board (28); and
covering the pressure sensor unit (30) with the seal plate (40) to
form a fluid seal between the pressure sensor unit (30) and the seal plate (40).
2. The method of claim 1, further comprising:
indexing a first receptacle element (26) on the circuit board (28) to
a locator feature (48), wherein indexing the alignment tool (100) to the circuit board (28)
includes aligning the locator feature (48) with a second receptacle element (146) on the
alignment tool (100).
3. The method of claim 2, wherein the first receptacle element (26)
on the circuit board (28) and the second receptacle element (146) on the alignment tool
(100) are substantially identical.
4. The method of claim 3, wherein the pressure sensor unit (30)
includes an array (14) of at least three pressure sensors (30).
5. The method of claim 4, wherein attaching the pressure sensor unit
(30) to the circuit board (28) includes soldering.
6. The method of claim 5, wherein indexing the seal plate (40) to the
circuit board (28) includes aligning the locator feature (48) with a third receptacle
element (46) on the seal plate (40), the third receptacle element (46) on the seal plate (40)
being substantially identical to the second receptacle element (146) on the alignment tool
(100).
7. An integrated seal module (10) for sealing one or more pressure
ports (53) to one or more pressure sources (16, 17, 18, 19, 20, 21), comprising:
a mounting plate (40) having a first surface (42) and a second
surface (44) on opposing sides thereof;
at least one locator hole (46) defined by the mounting plate (40)
and extending through the mounting plate (40) between the first and second surfaces (42,
44);
at least one pressure passage (52) defined by the mounting plate
(40) and extending through the mounting plate (40) between the first and second surfaces
(42, 44); and
a seal member (54) configured to effect a fluid seal between the
one or more pressure ports (53) and the first surface (42) and configured to effect a fluid
seal between the one or more pressure sources (16, 17, 18, 19, 20, 21) and the second
surface (44).
8. The seal module (10) of claim 7, further comprising a locator
bushing (50) disposed within the at least one locator hole (46).
9. The seal module (10) of claim 8, wherein the seal member (54) is a
liquid injection molded framework, wherein the liquid injection molded framework
includes portions (58) completely encased by the mounting plate (40).
10. The seal module (10) of claim 9, wherein the seal member (54) and
the locator bushing (50) are formed as a single continuous unit.
11. The seal module (10) of claim 10, wherein the one or more
pressure ports (53) include six pressure ports (53) and the one or more pressure sources
(16, 17, 18, 19, 20, 21) include six pressure sources (16, 17, 18, 19, 20, 21), and
wherein the at least one pressure passage (52) includes six pressure
passages (52), each configured to provide fluid communication between a respective one
of the six pressure ports (53) and a respective one of the six pressure sources (16, 17, 18,
19, 20, 21).
12. The seal module (10) of claim 11, further comprising:
one or more pressure sensors (30), wherein the one or more
pressure ports (53) are located on the one or more pressure sensors (30), respectively.
13. The seal module (10) of claim 12, wherein the one or more
pressure sensors (30) are small outline integrated circuits.
14. The seal module (10) of claim 13, wherein the one or more
pressure sensors (30) are overmolded in the mounting plate (40).
15. The seal module (10) of claim 13, further comprising one or more
cradles integrated into the mounting plate (40), wherein the one or more cradles are
configured to engage the one or more pressure sensors (30).

A method of assembling a pressure sensing module (15)
includes affixing a pressure sensor unit (30) to an
alignment tool (100) aod indexing the alignment tool
(100) to a circuit board (28). After the pressure
sensor unit (30) is attached to the circuit board (28),
a seal plate (40) is indexed thereto. A locator feature
(48) indexes receptacle elements on the circuit board
(28), alignment tool (100), and seal plate (40). An i
integrated seal module (10) includes a mounting plate
(40) having first and second opposing faces, and at
least one locator hole (46) and one or more pressure
passages (52) extending therethrough. A unitary seal
member (54) effects a fluid seal between the pressure
ports (53) and the first surface (42) and the pressure
sources (16, 17, 18, 19, 20, 21) and the second surface
(44). The seal member (54) and locator bushing (50) may
be formed as a single, continuous liquid injection
molded framework, including portions (58) encased by
the mounting plate (40). Pressure passages (52) provide
fluid to pressure sensors (30), which may be overmolded
in the mounting plate (40).