Broad Range Micro Pressure Sensor
Disclosed is a micro pressure sensor including a plurality of modules that are operative over different ranges of pressure. The modules include a stack of at least two module layers, each module layer including a module body having walls that define a compartment and with the defined compartment partitioned into at least two sub-compartments, a port for fluid ingress or egress disposed in a first wall of the body, with remaining walls of the body being solid walls, a membrane affixed to a first surface of the module body covering the compartment, and an electrode affixed over a surface of the membrane.
This application claims priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application Ser. No. 62/579,239, filed Oct. 31, 2017, and entitled “Broad Range Micro Pressure Sensor,” the entire contents of which is hereby incorporated by reference.
BACKGROUNDThis specification relates to pressure sensor devices and systems.
A pressure sensor detects or measures a fluid pressure, i.e., a force exerted by a fluid, being the force necessary to oppose the fluid from expanding. Pressure sensors are used in a variety of control and monitoring applications and can be used to indirectly measure other physical quantities such as fluid flow, fluid speed, and altitude. Typically, pressure sensors are fabricated using various techniques and technologies, each of which find use according to performance, application suitability and cost considerations.
Typical pressure sensors include transducers that generate an electrical signal as a function of the pressure imposed on the transducer, which is an example of a force collector type pressure sensor. A force collector type uses a force collector (such as diaphragm, piston, etc.) to measure strain (or deflection) resulting from a force applied to the force collector. Types of force collectors include piezo-resistive strain gauge types that use the piezo-resistive effect to detect strain due to applied pressure and a piezoelectric type that uses the piezoelectric effect in certain materials such as quartz, certain ceramics and certain polymers.
Another type is a capacitive type that uses a diaphragm and pressure cavity to create a variable capacitor to detect strain due to applied pressure. Common technologies use metal, ceramic, and silicon diaphragms. Such sensors can be fabricated using silicon MEMS (microelectromechanical systems) techniques.
SUMMARYAccording to an aspect, a pressure sensor includes a plurality of module stages, at least one of the plurality of module stages operative over a first range of pressure and at least one other of the plurality of module stages operative over a second, different range of pressure, with each module stage including a stack of at least two module layers, each module layer including a module body having walls that define a compartment and with the defined compartment partitioned into at least two sub-compartments, a port for fluid ingress or egress disposed in a first wall of the module body, with remaining walls of the module body being solid, a membrane affixed to a first surface of the module body covering the compartment, and an electrode affixed over a surface of the membrane.
According to an additional aspect, a micro pressure sensor includes a first module operative over a first range of pressure, the first module including a first stack of a first plurality of first module layers, each first module layer including a first module body having walls that define a compartment and with the defined compartment partitioned into at a first plurality of sub-compartments, a first port for fluid ingress or egress disposed in a first wall of the first module body, with remaining walls of the first module body being solid, a first membrane affixed to a first surface of the first module body covering the compartment, and a first electrode affixed over a surface of the first membrane. The micro pressure sensor further includes a second module operative over a second, different range of pressure, the second module affixed in the micro pressure sensor, the second module including a second stack of a second plurality of second module layers, each second module layer including a second module body having walls that define a compartment and with the defined compartment partitioned into at a second plurality of sub-compartments that are different in one or more of number and size of sub-compartments than the first plurality of sub-compartment, a second port for fluid ingress or egress disposed in a first wall of the second module body, with remaining walls of the second module body being solid walls, a second membrane affixed to a first surface of the second module body covering the compartment, and an electrode affixed over a surface of the membrane.
Other aspects include methods of fabrication.
The micro pressure sensors can be used for performing pressure sensing for a variety of industrial, medical, and biological applications. The micro pressure sensors can be fabricated using reasonably inexpensive techniques and thus provide inexpensive micro pressure sensors for various applications. In particular embodiments, the micro pressure sensors are fabricated using roll to roll manufacturing techniques. The micro pressure sensors are operable over a relatively wide range of pressures and have relatively high levels of sensitivity to pressure changes over wide ranges of pressure, relative to a micro pressure sensor comprised of standard sized compartment(s).
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention are apparent from the description and drawings, and from the claims.
Micro-pressure sensors described herein are made using micro fabrication methods and can be used for sensing pressure in various industrial, commercial, medical, and biological applications. The micro pressure sensors are fabricated on a micron/millimeter scale. Several fabrication techniques are disclosed.
One type of micro pressure sensors is a narrow pressure range micro pressure sensor as described in my published patent application US-2018-0038754-A1 assigned to the assignee of the present application, and which application is incorporated herein by reference in its entirety. By narrow range micro pressure sensor is meant that a given module will be operative over a narrow range of pressures relative to a broad range micro pressure sensor. The micro pressure sensor of the incorporated by reference application has a single chamber that is compartmentalized into plural compartments. Each compartment experiences and is responsive to the same pressure over a given range of pressure. The narrow range type is a micro pressure sensor having high sensitivities over a relatively narrow range of pressure (referred to herein as a narrow range micro pressure sensor).
Describe below is another type of micro pressure sensor that has high sensitivities over a broad range of pressures, as is referred to herein as a broad range micro pressure sensor. Two types of broad range micro pressure sensors are described, a broad range micro pressure sensor 10 and a stacked broad range micro pressure sensor 100.
Broad Range Micro Pressure SensorReferring to
As will be illustrated in more detail in
Membranes 18a-18f are anchored between the two end walls 16a, 16b and the front and back walls and on walls, e.g., 17a, 17b that divide the chamber 20 into the plural sub-compartments 23a-23b. While the membranes 18a-18f separate the chamber 20 into plural compartments 21a-21g, the walls (two of which) 17a, 17b are shown and other walls (not shown in
A first set of ports 12a-12c are disposed through wall 13a for fluid access into each of compartments 21b, 21d and 21f, respectively. A second set of ports 14a-14d, are disposed through wall 13b for fluid access into each of compartments 21a, 21c, 21e and 21g, respectively. In this implementation, each compartment 21a-21b includes a port either from the first set of ports 12a-12c or from the second set of ports 14a-14d, but not both, defined in the respective walls. For example, the compartment 21a includes the port 14a in the wall 13b, while the port of the wall 13a in the region of compartment 21a is solid, without any opening.
As will be discussed below the plural sub-compartments, e.g., sub-compartments 23a-23b will provide different degrees of sensitivity within a single compartment to different pressures and pressure ranges.
In
As shown in
The compartments 21a-21g are fluidic-ally sealed from each other, but each of the sub-compartments within a sub-compartment are fluidic-ally coupled. Two compartments 21a and 21g at the opposite ends of the micro pressure sensor 10 have walls provided by the fixed walls 16a, 16b of the body and a corresponding membrane. Intermediate compartments 21b-21f between the compartments have walls provided by two adjacent membranes with the micro pressure sensor 10 having at least one and generally many intermediate compartments, each of which intermediate compartment walls are provided by two membranes 18a-18f. The micro pressure sensor 10 can sense changes in pressure from a rest position as is illustrated in
In the implementations discussed below, pressures are relative to ambient pressure of ambient air. However, other references may be used.
Also, in the discussion below broad range micro pressure sensors are relative to a narrow range micro pressure sensor. While the discussion below will focus on broad range micro pressure sensors, it would be helpful to first define a narrow range micro pressure sensor, and to discuss general features and operational characteristics common to both narrow and broad range micro pressure sensors.
A narrow range micro pressure sensor is comprised of one or more standard pressure sensor chambers 20 that have identical pressure sensor characteristics, i.e., sensitivity over a narrow pressure range. A standard pressure sensor chamber 20 is defined as a single chamber that has at least two compartments (and which could have many such compartments) with each of the compartment being identical in pressure sensing characteristics. One way for compartments to be identical in pressure sensing characteristics is by having the compartments being identical in size, volume, elastic characteristics of the membranes, and characteristics of electrodes.
A narrow range pressure sensor will have high sensitivity over a defined, yet relatively limited, i.e., narrow, range of pressure in comparison to the broad range micro pressure sensor 10. The range of sensitivity to pressure is based on the size and volume characteristics of compartments, elastic characteristics of the membranes (Young's modulus and thickness), and characteristics of electrodes (pattern, thickness, etc.) that affect changes in capacitance measured between electrodes of the micro pressure sensor.
With either the narrow or the broad range micro pressure sensors, although six membranes 18a-18f are shown in
Each membrane 18a-18f has an electrode (not explicitly shown in
When an external fluid is fed to the micro pressure sensor 10 at the same pressure at the reference pressure, the membranes 18a-18f and thus electrodes are not flexed and the membranes/electrodes are at nominal, rest (quiescent) positions, such as shown in
When activated, by application of a pressure, the membranes 18a-18f and thus electrodes flex, changing the volume of the respective compartments and more particularly, the distance separating pairs of electrodes on such membranes 18a-18f. These changes in distance separating pairs of electrodes cause changes in capacitance between pairs of adjacent electrodes, as shown for 18a, 18b in
Changes in volume can be considered as an alternative way to represent pressure changes. A capacitance characteristic is provided by a pair of adjacent electrodes that are separated by a dielectric, e.g., contents of a compartment (i.e., the fluid) and/or the dielectric property of the membrane.
A capacitor is effectively provided by the combination of a pair of electrodes on a pair of adjacent membranes that are separated by distance provided from the respective compartment. A capacitance characteristic of such effective capacitor is determined by the dielectric constant provided by one of the pair of adjacent membranes, the dielectric of the fluid in the compartment, the area of the electrodes and distance that separates the electrodes, e.g., generally at least approximated by a formula for a parallel plate capacitor, given as:
C=εrε0A/d, where
C is the capacitance, in farads;
A is the area of overlap of the two electrodes, in square meters;
εr is the dielectric constant of the material between the electrodes (sum of dielectric constants of a membrane and fluid);
ε0 is the electric constant (ε0≈8.854×10-12 F·m−1); and
d is the separation between the plates, in meters. where d is sufficiently small with respect to the smallest chord of A.
A controller (see
In some embodiments, the distance between two adjacent membranes 18a-18b in their nominal positions is about 50 microns. In some implementations, each of the compartments 21a-21g can have similar nominal volumes Ve. In such implementations, the distance between the membrane 18a in its nominal position and the end wall 16a or between the membrane 18f in its nominal position and the end wall 16b is about 50 microns. The compartments 21a-21g can also have different sizes. The sizes can be chosen based on, e.g., manufacturing, power consumption, and application considerations. As an example, the micro pressure sensor 10 can have a length of about 1.5 mm, a width of about 1.5 mm, a total height (the cumulative height of different compartments) of 0.05 mm, and a total volume of about 0.1125 mm3. Other configurations are possible.
Compared to a conventional pressure sensor used for similar purposes, the micro pressure sensor 10 may use less material, and thus is subject to less stress. The micro pressure sensor 10 has a size in the micron to millimeter scale, and can provide wide ranges of pressure measurements.
In other embodiments, the ports can be on adjacent sides or indeed on the same side, provided that ports acting as inlets or input ports are separated from ports acting as outlets or output ports, by such ports being coupled to different vessels that provide the fluid whose pressure is being measured and the reference. The described micro pressure sensor 10 is a capacitance type of sensor. Sensing occurs in either of two alternating operations of a fluid overpressure and fluid under pressure in the chamber 20 of the micro pressure sensor 10.
Referring to
In the overpressure operation (
However, as the overpressure increases, the increased overpressure will cause additional flexure of the membranes 18a-18f covering the sub-compartments 23a, but will start flexing the membranes 18a-18f portions over sub-compartments 23b in response to the increased overpressure applied to ports 12a, 12b and 12c acting as inlets.
Referring now to
The expansion occurs in the end compartments 12a, 21g when membranes 18a, 18f move away from end walls 16a, 16b and for compartments 21c, 21d when adjacent membranes 18b, 18c and 18 move away from each other. The movement of these membranes increases the volume of the respective end compartments 21a, 21g and intermediate compartments 21c, 21d, in those portions of the compartments that are part of the sub-compartment 23a, but not sub-compartment 23b due to the charge of fluid (gas or liquid) into the compartments coupled to the ambient or reference. Simultaneous to the expansion of those compartments, adjacent compartments 21b, 21d and 21f (all here being intermediate compartments) are discharged when respective sets of membranes move towards each other to reduce the respective compartment volumes in those portions of the compartments that are part of the sub-compartment 23a, but not sub-compartment 23b.
In the under pressure operation (
As with
Removal of the over pressure or the under pressure applied to the ports returns the micro pressure sensor 10 to the nominal state of
The micro pressure sensor 10 discussed above thus comprises multiple membranes 18a-18f each anchored between two fixed walls 13a, 13b and two fixed walls not shown in those views. The fixed walls 13a, 13b and the not depicted walls are body layers that form multiple compartments separated by pairs of adjacent membranes. The first and last ones of the compartments are formed by a membrane and a fixed wall that is part of an end cap of the body, but intermediate compartments are provided by pairs of adjacent membranes. Each of the compartments 21a-21g is divided into plural sub-compartments (sub-compartments 23a, 23b shown) and portions of the membranes 18a-18f covering those portions of the sub-compartments 23a and 23b will flex according to the extent of the overpressure or under-pressure applied to the chamber 20, as a whole.
Comparing
Electrodes (not explicitly shown in
Micro pressure sensors having the above described features can be manufactured using various methods such as MEMS processing techniques and so-called roll to roll (R2R) processing. The materials for a micro pressure sensor 10 are chosen based on the features to be provided by the micro pressure sensor 10 and the method of manufacturing of the micro pressure sensor 10. Below are some criteria for choosing the materials of the different parts of micro pressure sensor 10.
Sensor body—The material used for the body may be defined by the requirements. In general, the material needs to be strong or stiff enough to hold its shape to produce the compartment volume. In some implementations, the material is etchable or photo sensitive so that its features can be defined and machined/developed. Sometimes it is also desirable that the material interact well, e.g., adheres, with the other materials in the sensor. Furthermore, the material is electrically non-conductive. Examples of suitable materials include SU8 (negative epoxy resist), and PMMA (Polymethyl methacrylate) resist.
Membrane—The material for this part forms a tympanic structure that charges and discharges fluid in the chamber. As such, the material is required to bend or stretch back and forth over a desired distance and have elastic characteristics. The membrane material is impermeable to the fluids of interest, including gas and liquids, is electrically non-conductive, and can have either a low or a high breakdown voltage characteristic. Examples of suitable materials include silicon nitride, and Teflon. Others are possible.
Electrodes—The material of the electrodes is electrically conductive. Because the electrodes do not conduct significant amounts of current, the material can have a high electrical sheet resistance, although the high resistance feature is not necessarily desirable. The electrodes are subject to bending and stretching with the membranes, and therefore, it is desirable that the material is supple to handle the bending and stretching without fatigue and failure. In addition, the electrode material and the membrane material adhere well, e.g., do not delaminate from each other, under the conditions of operation. Examples of suitable materials include very thin layers of gold and platinum. Others are possible.
Electrical interconnects—The voltages from the capacitance measurement circuits are conducted to the electrode on each membrane of each compartment. Electrically conducting paths to these electrodes can be built using conductive materials, e.g., gold and platinum.
Other materials—when MEMS processing is used in manufacturing the micro pressure sensor, a sacrificial filling material, e.g., polyvinyl alcohol (PVA), can be used. The sacrificial filling material may also be used in R2R processing. In some implementations, solvents are used in the manufacturing process, which may place additional requirements on the various building materials of the micro pressure sensor. It may be possible to print some of the electrical circuit components onto the membranes. In general, while certain materials have been specified above, other materials having similar properties to those mentioned could be used.
Referring now to
The modularized broad range micro pressure sensor 100 differs from the modularized broad range micro pressure sensor 10 (
Each of the three stages 102a-102c is comprised of at least one and generally several or many module layers 105a-105c. In
Referring to
The electrodes can be a pre-prepared sheet to be attached to the other elements, the electrodes can be formed directly onto those elements, e.g., by printing or with other techniques discussed below. Thus multiple, e.g., two, three, or any desired number of, modules and module layers are stacked on top of each other to form multiple intermediate compartments in a modularized, stacked micro pressure sensor 100. In the stack, each membrane is separated by the body and each body is separated by a membrane. To form a complete modularized, stacked micro pressure sensor 100, the end caps are placed on each of the top and bottom ends of the stack of modules so that the end caps on the modules form two fixed end walls of the modularized, stacked micro pressure sensor, as shown in
Each of the three stages 102a-102c are configured to be highly sensitive to a specific range of pressures. That is one stage, e.g., stage 102a is highly sensitivity to pressure in a given pressure range, e.g., R1, whereas stages 102b and 102c provide a relatively small contribution to sensitivity to pressures in the pressure range R1, but each of the stages 102b-102c are highly sensitivity to pressures in given pressure ranges R2 and R3 respectively, while providing a relatively small contributions to sensitivity to pressure changes outside of their respective pressure ranges.
Also shown in
Referring now to
Several approaches can be used to provide the micro pressure sensor 100. Fundamentally, common to all approaches is fabrication of plural modules that have corresponding high sensitivities to different pressure ranges. Such plural modules that have corresponding high sensitivities can be configured to have plural sub-compartments (each of at least two sub-compartments) having high sensitivities to different pressure ranges.
One mechanism to provide high sensitivity over broader ranges of pressure for a given standard size chamber is make the membranes of different stiffness relative to each other. Described now is a mechanism to provide membranes with different ‘effective’ stiffness by providing different aperture sizes within a compartment to make the membrane effectively more or less stiff. In general, the stiffer the membrane the more pressure would be required to flex the membrane.
Referring now to
In
Again for reference, a standard size compartment can be defined. While a standard size compartment could be of any size, for discussion herein it is nominally 1.5 mm long by 1.5 mm wide by 50 microns high. Each complex patterned compartment is formed from the micro sensor body material by patterning that material to form plural sub compartments that define the particular complex pattern within the standard size compartment (examples of which were shown in
Again with respect to the standard size compartment reference, the complex pattern compartment can be any pattern that leaves body material within portions of the otherwise standard size compartment forming plural sub compartments within the standard size compartment.
The membranes carry electrodes and a compartment is bounded by a pair of membranes each of which carries a corresponding electrode.
With the complex pattern compartment of
Referring now back to
Up to 2 psi the amount of flexure of the membrane 105b will be relatively minimal. This is because the sizing (surface area) of the sub-compartments 23a and 23b is selected to be minimally responsive to pressures below 2 psi. The sensitivity (change in capacitance vs. change in pressure) can be modeled knowing the Young's modulus of the membrane/electrode combination, surface area of the aperture, dielectric constants of material between pairs of electrodes, size of the electrodes, and height of the aperture, generally as discussed above. At or slightly above 2 psi, the portion of the membrane over the sub-compartments 23a, 23b will start to flex.
However, the amount of flexure of the membrane 105b at or slightly above 2 psi over the sub-compartment 23a will substantially more than the amount of flexure over the sub-compartments 23b. The relative amounts of flexure would be related to differences in surface area of membrane portions over the sub-compartments 23a and 23b, because the membrane 105b is affixed to the body layer along the frame of the body as well as interior portions, thus effectively providing individual membranes over each of the sub-compartments 23a, 24a. At some pressure above 2 psi, but below 4 psi, the membrane portion over the sub-compartment 23a will no longer be responsive, and both membrane 105b and a corresponding membrane 105b from an adjacent module layer 105 will come together and touch.
However, the membrane portions over the sub-compartments 23b will still be responsive to pressure changes and thus will provide concomitant changes in capacitance. Thus, each distinct pair of electrodes on membranes covering provide effectively a fixed or bulk capacitance and a variable capacitance in parallel. Each module and each sub-compartment likewise effectively a fixed or bulk capacitance and a variable capacitance all of which are in parallel and thus add together to provide a total fixed or bulk capacitance and total variable capacitance. Design considerations to consider include the provision that no sub-compartment should exhibit a maximum pressure that will cause the membrane to flex and exceed the elastic limit of the material of the membrane.
Each stage 102a-102c therefore can be comprised of plural module layers 105 and within a given stage 102a-102c, the plural module layers 105 can be of one of the types discussed in
Referring back to
Each membrane of the micro pressure sensor 100 moves in two opposite directions relative to its central, nominal position. In response to a pressure difference on either side of a membrane, the membrane flexes to either expand or reduce a distance itself and an adjacent membrane and thus between a pair of electrodes carried by itself and the adjacent membrane, and concomitant therewith either increasing or decreasing a capacitance value of an effective capacitor provided between the two electrodes. The membrane travels a distance less than, e.g., half of, the height of the compartment. As a result, the membrane experiences less flexing and less stress, leading to longer life and allowing for greater choice of materials.
In addition, because each one of the membranes carries but one electrode, and capacitance is being sensed, these capacitors and more specifically these electrodes can be connected, such that the capacitors are connected in parallel. Capacitors connected in parallel add in capacitance. Thus by connecting the capacitors formed by the membranes and pairs of electrodes in parallel, the modularized broad range micro pressure sensor 100 will have a higher bulk capacitance and a higher range of variable capacitance, and thus greater sensitivity (change in pressure per change in capacitance) compared a single capacitor formed by a single membrane and pair of electrodes. Exemplary values for sensitivity can be such as 0.02 pf capacitance change per 0.05 psi change over a range of 0.0 to 100 psi. Other ranges and sensitivities can be provided by different selections of materials and dimensions of a compartment and sub compartments, as well as providing more or few module layers per module and more or fewer modules per modularized broad range micro pressure sensor 100.
The membranes, the end caps, and the body can have the same dimensions, and the electrodes can have smaller dimensions than the membrane or the other elements. In some implementations, the membrane has a dimension of about microns by microns to about millimeters by millimeters, and a thickness of about 5 microns. The body has an outer dimension of about microns by microns to about millimeters by millimeters, a thickness of about 50 microns, and an inner dimension of about microns by microns to about millimeters by millimeters. The thickness of the body defines the nominal size of the compartment (similar to compartments
Referring now to
Roll to Roll Processing for Producing Micro Pressure Sensors
Referring to
The original raw material roll is of a web of flexible material. In roll to roll processing the web of flexible material can be any such material and is typically glass or a plastic or a stainless steel. While any of these materials (or others) could be used, plastic has the advantage of lower cost considerations over glass and stainless steel. Specific materials will be determined according to the application of the micro pressure sensor. In applications materials such as stainless steel or other materials that can withstand encountered temperatures would be used, such as Teflon and other plastics that can withstand encountered temperatures.
For the structures shown in
The plastic web is used to support the body by a deposition of material on the web at a deposition station followed by patterning station. The body is formed at a forming station. The web having the body has a membrane deposited over the body at a station. Over the membrane is deposited an electrode at deposition station which is patterned at patterning station. Membrane sheet with patterned electrodes supported on the membrane are provided on the body. Electrical interconnects, for connecting to the electrodes on each membrane, are provided by depositing conductive materials, e.g., gold, silver, and platinum layers (or conductive inks such as silver inks and the like). In some implementations some of the electrical circuit components are printed onto the membranes.
The roll having the micro module units (body and membrane with electrode and electrical connections) are diced and the micro module units are collected, assembled into stacks of micro modules, and packaged by including the end and top caps to provide the micro pressure sensor 10 or 100. Depending upon the layout of the units on the web it may be possible to fold the web of the module units into a stack of units, with electrodes provided on the membrane layer or whole layers of many units can be laminated together to produce a stack prior to being diced and packaged.
The membrane material is required to bend or stretch back and forth over a desired distance and thus should have elastic characteristics. The membrane material is impermeable to fluids, including gas and liquids, is electrically non-conductive, and possesses a high breakdown voltage. Examples of suitable materials include silicon nitride and Teflon.
The material of the electrodes is electrically conductive. The electrodes do not conduct significant current. The electrodes are subject to bending and stretching with the membranes, and therefore, it is desirable that the material is supple to handle the bending and stretching without fatigue and failure. In addition, the electrode material and the membrane material adhere well, e.g., do not delaminate from each other, under the conditions of operation. Examples of suitable materials include, e.g., gold, silver, and platinum layers (or conductive inks such as silver inks and the like). A release material can be used for allowing for valve movement. Suitable release materials include, e.g., the sacrificial filling material mentioned above.
Referring to
Referring to
For the micro pressure sensor 10 or 100, the layers would have thicknesses as mentioned above approximately 50 microns for the body layers and 5 microns for the membrane elements of the micro pressure sensor. However, other thicknesses are possible. The sheet is micro-machined using a mask or direct write to configure a laser ablation station to define or form sub-compartments for micro pressure sensor 10 or 100 (e.g., the complex patterned sub-compartments as desired examples shown in
Referring now to
Prior to lamination of the second sheet to the first sheet, the second sheet is also provided with several randomly dispersed holes or view ports (not shown) over some areas that will be in alignment with the body structures. These randomly dispersed holes are used by a machine vision system to reveal and recognize underlying features of the body units on the first sheet. Data is generated by noting the recognized features in the first sheet through the random holes. These data will be used to align a third ablation station when forming electrodes from the layer over the bodies.
The second sheet is laminated to and thus sticks (or adheres) to the first sheet in areas where there is plastic on the first sheet and plastic on the second sheet. At this point, a composite sheet of repeatable units of the micro pressure sensor are formed, but without electrodes formed from the layer on the membrane.
The machine vision system produces a data file that is used by the laser ablation system in aligning a laser ablation station with a mask (or direct write) such that a laser beam from the laser ablation system provides the electrodes according to the mask, with the electrodes in registration with the corresponding portions of the bodies. The electrodes are formed by ablating away the metal in regions that are not part of the electrodes and conductors, leaving isolated electrodes and conductors on the sheet. The registration of the patterned electrodes to the body is thus provided by using the machine vision system to observe features on the front side of the laminated structure providing positioning data that the laser ablation system uses to align a laser beam with a mask, using techniques commonly found in the industry.
Referring now to
A jig (not shown) that can comprises vertical four posts mounted to a horizontal base is used to stack individual ones of the cut dies. On the jig an end cap (e.g., a 50 micron PET sheet with a metal layer) is provided and over the end cap a first repeatable unit is provided. The repeatable unit is spot welded (applying a localized heating source) to hold the unit in place on the jig. As each repeatable unit is stacked over a previous repeatable unit that unit is spot welded. The stack is provided by having ports on one side of the stack and ports on the other of the stack, and staggered resulting from arrangement of the valves so as to have a solid surface separating each of the ports in the stack (See
Referring now to
Elements of different implementations described herein may be combined to form other embodiments not specifically set forth above. Elements may be left out of the structures described herein without adversely affecting their operation. Furthermore, various separate elements may be combined into one or more individual elements to perform the functions described herein. In addition, while pressure modules are illustrated in a stack other arrangements may be possible, including pressure modules adjacent to each other and spaced from each other, provided that the pressure modules are outfitted with corresponding end caps and have inlets and outlets being fed from a common pressure source and a common reference. In addition, the electrodes on membranes can be patterned to correspond to underlying patterned sub-compartments (with concomitant increase in the number of capacitances that need to be measured and interconnected) and a membrane for a given module can be single membrane or can be divided into individual membranes corresponding to the underlying patterned sub-compartments. Other embodiments are within the scope of the following claims.
Claims
1-20. (canceled)
21. A method of manufacturing a micro pressure sensor, method comprising:
- patterning a sheet of material to produce body elements having peripheral walls, with the body elements further patterned into at least two compartments, with the at least two compartments defined by the peripheral walls of the body elements and interior walls of the body elements, with portions of the interior walls having openings to allow fluid ingress and egress among the at least two compartments, and the peripheral walls having a single opening to allow only one of fluid ingress into the body element or fluid egress out of the body element;
- affixing to the body elements, a sheet of a flexible material, with the sheet of flexible material being flexible relative to the material of the sheet that produced the body elements, the sheet of flexible material having a conductive surface layer;
- dicing the affixed body elements to produce module layers; and
- stacking the module layers one over the other, according to whether the single opening in a given module layer provides the fluid ingress into the body element or the fluid egress out of the body element producing the micro pressure sensor.
22. The method of claim of 21 further comprising:
- patterning the conductive layers into isolated regions to provide electrodes.
23. The method of claim of 21 further comprising:
- patterning the conductive layers to produce electrodes having tabs for connection to an external circuit.
24. The method of claim of 21 further comprising:
- affixing the stack of module layer between a pair of end caps.
25. The method of claim of 24 wherein patterning the sheet to provide the body elements, further comprises:
- patterning the sheet to provide holes through portions of the peripheral walls of the body element;
- forming through the holes, conductive vias to contact corresponding ones of the module layers.
26. (canceled)
26. The method of claim of 21 wherein patterning the sheet to provide the body elements, further comprises:
- patterning the sheet to produce the opening in a first peripheral wall of each of the body elements.
27. The method of claim of 21 further comprises:
- applying end caps to over a first one and a last one the module layers in the stack.
28. The method of claim of 25 wherein four holes are provided and each module has one hole that contacts one tab and four modules are used to contact each of four holes.
29. The method of claim 28 wherein patterning the more than two compartments, further comprises:
- patterning a first number of the body elements into a first number of more than two compartments and a second number of the body elements into a second, different number compartments, with the second, different number being greater than the first number.
30. The method of claim 29 further comprising:
- stacking first module layers produced from the first number of body elements into a first group having the first number of the plurality of compartments; and
- stacking second module layers produced from the second number of body elements into a second group having the second number of the plurality of compartments.
31. The method of claim 21 further comprising:
- configuring the single openings of a first set of the module layers, as inlet ports with remaining walls of the first set of the module layers being solid walls; and
- configuring the single openings of a second set of the module layers, as reference ports with remaining walls of the second set of the module layers being solid walls.
32. The method of claim 31 further comprising:
- arranging in the stacking of the module layers the first set of the plurality of module layers into a first number of compartments that are of at least two different surface areas; and
- arranging in the stacking of the module layers of last ones of the plurality of module layers into a second number of compartments that are more than the least two different surface areas, and with the second number being greater than the first number.
33. A method of manufacturing a micro pressure sensor, method comprising:
- patterning a sheet of material to produce body elements having peripheral walls and at least two compartments that are defined by the peripheral walls of the body elements and interior walls of the body elements, with portions of the interior walls having openings to allow fluid ingress and egress among the at least two compartments, and a single one of the peripheral walls having an opening to allow only one of fluid ingress into the body element or fluid egress out of the body element, with remaining peripheral walls being solid walls;
- affixing a sheet of a flexible material over surfaces of the body elements, with the sheet of flexible material being flexible relative to the material of the sheet that produced the body elements, and with the sheet of flexible material having a conductive surface layer;
- dicing the affixed sheet to produce module layers; and
- stacking the module layers one over the other, according to whether the single opening in a given one of the module layers provides the fluid ingress into the body element or the fluid egress out of the body element, to produce the micro pressure sensor.
34. The method of claim of 33, further comprises:
- patterning the conductive layers into isolated regions to provide electrodes.
35. The method of claim of 33, further comprises:
- patterning the conductive layers to produce electrodes having tabs for connection to an external circuit.
36. The method of claim of 33, further comprises:
- affixing the stack of module layers between a pair of end caps.
37. The method of claim of 33 wherein patterning the sheet to provide the body elements, further comprises:
- patterning the sheet to produce the single opening in a first peripheral wall of each of the body elements.
38. The method of claim 33 wherein patterning the sheet to produce the least two compartments, further comprises:
- patterning the at least two compartments into a plurality of more than two compartments that are defined by interior walls that have openings to allow fluid ingress and egress among the plurality of compartments.
39. The method of claim 38 wherein patterning the at least two compartments into the plurality of more than two compartments, comprises:
- patterning a first number of the module layers into a first number of the plurality of the more than two compartments and a second number of the module layers into a second greater number of the plurality of compartments.
40. The method of claim 29 further comprising:
- stacking the first module layers into a first group having the first number of the plurality of compartments; and
- stacking the second module layers into a second group having the second number of the plurality of compartments, with the second number being greater than the first number.
41. The method of claim 33, further comprising:
- configuring a first set of the single openings as inlet ports with remaining walls of the module layers being solid walls; and
- configuring a second set of the single openings as reference ports with remaining walls of the module layers being solid walls.
Type: Application
Filed: Jun 3, 2021
Publication Date: Oct 21, 2021
Inventor: Stephen A. Marsh (Carlisle, MA)
Application Number: 17/337,589