METHOD AND APPARATUS FOR PRESSURE MEASUREMENT USING QUARTZ CRYSTAL
BACKGROUND OF THE INVENTION
The present invention relates to measurement of pressures in an industrial processes. More specifically, the present invention relates to measuring a pressure with quartz crystal.
Industrial processes are used in the manufacturing and transport of many types of materials. In such systems, it is often required to measure different types of pressure within the process. One type of pressure which is frequently measured is a differential pressure which is the pressure difference between one point in the process and another point in the process. For example, the differential pressure across an orifice plate in a tube containing a flow of process fluid is related to the flow rate of the fluid. Differential pressures can also be used, for example, to measure height of a process fluid in a tank or other container.
In such industrial processes, the pressure sensors are typically contained in, or coupled to, a pressure transmitter which is located at a remote location and transmits the pressure information back to a centralized location such as a control room. The transmission is frequently over a process control loop. For example, a two wire process control loop is often used in which two wires are used to carry both information as well as power to the transmitter. Wireless communication techniques may also be used.
In many process installations, it is also desirable to measure an absolute or gauge pressure, herein referred to a "line pressure", of the process. This information can be used, for example, to provide more accurate flow measurements by including changes in density of the process fluid in the flow
calculations. Typically, the additional pressure measurement requires an additional pressure sensor coupled to the process fluid. For example, an additional pressure transmitter can be deployed which includes a line pressure sensor and coupled to the two wire process control loop.
SUMMARY
A pressure sensor includes a sensor body which is arranged to couple to a process pressure. A quartz crystal is coupled to the sensor body and is configured to measure pressure of fluid in the sensor body.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 shows a process measurement system with a process transmitter constructed in accordance with the present invention.
Figure 2 is schematic view of a transmitter of Figure 1.
Figure 3 shows a cross sectional view of a portion of the process transmitter of Figure 1.
Figure 4 is a simplified diagram showing line pressure measurement in one example configuration.
Figure 5 is a cross-sectional view of an embodiment of the present invention configured to measure line pressure using a quartz sensor.
Figure 6 is a simplified diagram of circuitry configured to measure pressure using a quart crystal sensor.
Figure 7 is a diagram which illustrates stresses on a sensor.
Figure 8A is a side plan view, Figure 8B is a side cross-sectional view, Figure 8C is a front plan view, Figure 8D is a side plan view and Figure 8E is a perspective view of a pressure sensor using a quartz crystal.
Figure 9 is a side cross-sectional view of another example embodiment using a tuning fork configuration.
Figure 1OA is a side cross-sectional view of a float pipe and Figure 1OB is a side view of a quartz sensor arranged to measure differential pressure.
DETAILED DESCRIPTION
In one embodiment, the present invention provides an apparatus and method for determining line pressure in a differential pressure measurement configuration. More specifically, in one aspect, the present invention monitors deformations in a capillary tube used to couple a differential pressure sensor to process fluid. These deformations are related to line pressure of the process fluid. In other embodiments, the present invention provides techniques for measuring a pressure based upon deformation of a vessel. In another embodiment, the present invention provides a sensor for measuring line pressure.
Figure 1 shows generally the environment of a process measurement system 32. Figure 1 shows process piping 30 containing a fluid under pressure coupled to the process measurement system 32 for measuring a process pressure. The process measurement system 32 includes impulse piping 34 connected to the piping 30. The impulse piping 34 is connected to a process pressure transmitter 36. A primary element 33, such as an orifice plate, venturi tube, flow nozzle, and so on, contacts the process fluid at a location in the process piping 30 between the pipes of the impulse piping 34. The primary element 33 causes a pressure change in the fluid as it passes past the primary element 33.
Transmitter 36 is a process measurement device that receives process pressures through the impulse piping 34. The transmitter 36 senses a differential process pressure and converts it to a standardized transmission signal that is a function of the process pressure.
-A-
A process loop 38 provides both a power signal to the transmitter 36 from control room 40 and bi-directional communication, and can be constructed in accordance with a number of process communication protocols. In the illustrated example, the process loop 38 is a two- wire loop. The two- wire loop is used to transmit all power to and all communications to and from the transmitter 36 during normal operations with a 4-20 rriA signal. A computer 42 or other information handling system through modem 44, or other network interface, is used for communication with the transmitter 36. A remote voltage power supply 46 powers the transmitter 36. In another example configuration, loop 38 is a wireless connection in which data may be transmitted or received with out the need of wires extending between the transmitter 36 and the control room 40. In other example configurations, data is transmitted and/or received wirelessly using a wireless communication protocol.
Figure 2 is a simplified block diagram of pressure transmitter 36. Pressure transmitter 36 includes a sensor module 52 and an electronics board 72 coupled together through a databus 66. Sensor module electronics 60 couples to pressure sensor 56 which received an applied differential pressure 54. The data connection 58 couples sensor 56 to an analog to digital converter 62. An optional temperature sensor 63 is also illustrated along with sensor module memory 64. The electronics board 72 includes a microcomputer system 74, electronics memory module 76, digital to analog signal conversion 78 and digital communication block 80.
Also illustrated in Figure 2 are capillary or "fill" tubes 93 and 94 which are used to couple the differential pressure sensor 56 to the process fluid 54. Isolation diaphragms 90 receive pressures from the process fluid 54 which is responsibly applied to a fill fluid carried in capillary tubes 93 and 94.
Through this fill fluid, the pressures of the industrial process are applied to the differential pressure sensor 56.
In accordance with the present invention, a deformation sensor 98 couples to a capillary tube 93 and is arranged to monitor deformation of the capillary tube 93. These deformations are related to the line pressure of the industrial process and the sensor 98 provides an output signal to analog to digital converter 62 or to line pressure measurement circuitry 99. In one aspect, any type of sensor can be used which is responsive to deformations of the tube. Circuitry 99 can be stand alone circuitry or, in some configurations, may be embodied in other circuitry used to measure the differential pressure. For example, some or all of the components used to monitor the various sensors may be shared components.
Figure 3 is a simplified cross sectional view of one embodiment of the present invention illustrating the deformation sensor 98. As discussed above, pressure sensor 56 couples to a process fluid through isolation diaphragms 90 which isolate the process fluid from cavities 92. Cavities 92 couple to the pressure sensor module 56 through impulse piping 93 and 94. A substantially incompressible fill fluid fills cavities 92 and impulse piping 93 and 94. When a pressure from the process fluid is applied to diaphragms 90, it is transferred to parts in cavities 132 and 134 of the pressure sensor 56.
Pressure sensor 56 is formed from two pressure sensor halves 114 and 116 and filled with a preferably brittle, substantially incompressible material 105. A diaphragm 106 is suspended within a cavity 132,134 formed within the sensor 56. An outer wall of the cavity 132, 134 carries electrodes 146,144,148 and 150. These can, generally, be referred to as primary electrodes 144 and 148, and secondary or secondary electrodes 146 and 150. These electrodes form
capacitors with respect to the moveable diaphragm 106. The capacitors, again, can be referred to as primary and secondary capacitors.
As illustrated in Figure 3, the various electrodes in sensor 56 are coupled to analog to digital converter 62 over electrical connection 103, 104, 108 and 110. Additionally, the deflectable diaphragm 106 couples to analog to sensor module electronics 60 through connection 109. Techniques for measuring the differential pressure are described in U.S. Patent No. 6,295,875 entitled "PROCESS PRESSURE MEASUREMENT DEVICES WITH IMPROVED ERROR COMPENSATION" issued October 2, 2001, to Rosemount Inc.
The deformation sensor 98 may take various configurations. A number of example techniques for measuring the deformation are described below. However, in one broad aspect, the present invention is not limited to these particular techniques and any technique used to measure deformation may be employed including those that are not specifically discussed herein.
The line pressure from the process fluid causes the capillary tube 93 to change shape. For example, an increased line pressure may cause the capillary tube 93 to expand. Similarly, an increased line pressure may cause any bends in the capillary tube 93 to become straighter. These, or other deformations of a capillary tube, can be monitored or otherwise measured and correlated with the line pressure of the process fluid.
Figure 4 is a simplified cross sectional view 150 of one example embodiment of the present invention. In the configuration of Figure 4, a differential pressure sensor 148 is coupled to a process fluid to isolation diaphragms 152 and 154 through capillary tubes 156 and 158, respectively. Straight portions 160 and 162 of the capillary tubes 156, 158, respectively, are provided and may be used as fill tubes to fill the capillary tubes with fill fluid. These portions can be separate tubes or formed integral with tubes 156,158.
Although these are shown as separate tubes, they may be formed as a single tube with tubes 156,158. Portion 162 includes a deformation sensor 170 which is configured to measure deformation of the fill tube.
The deformation sensor 98 may take various configurations. A number of example techniques for measuring the deformation are possible and the present invention is not limited to any particular technique. A wide variety of techniques can be used to measure deformation, including those that are not specifically discussed herein.
As referenced above, any appropriate technique can be used to measure the deformation of the tube or other physical property of the tube including a change in the stiffness of the tube. These techniques include strain gauge techniques, measurements of resonance, and others. Any physical property of the tube which changes with pressure may be measured and used in accordance with the present invention. The tube can be configured to enhance sensitivity, for example by varying the thickness of the tube. Tube geometry may also be selected to enhance performance and amplify the sensor signal. As discussed above, a differential measurement may be obtained by measuring physical changes in both of the capillary tubes.
In the present embodiment, the pressure sensor 170 is implemented using a frequency modulated vibrating quartz sensor. In some applications, this may be preferable due to the inherent digital nature of the output signal. When quartz is used as a sensor material it provides excellent stability of bias frequency and span. In addition, quartz has relatively low temperature sensitive activity. The piezo electric property of a quartz crystal can be used to provide a means of sustaining vibration using an oscillator circuit. The present invention includes a non-intrusive external piezo electric sensor is coupled to an oil fill tube. An oil fill tube is one example of a sensor body and
the invention is not limited to this configuration. Further, the pressure sensor of the present invention can be used alone, or in combination with another pressure sensor such as a gauge, absolute or differential pressure sensor. The coupling may be internal or external. The pressure inside the fill tube changes the resonate frequency of the external quartz structure. Using a quartz resonator to measure pressure is known in the art. However, the present invention provides a non-intrusive configuration for such measurements.
Figure 5 is a cross-sectional view of pressure sensor 170. Pressure sensor 170 includes an oil filled tube 400 having a sealed end 402 and an open end 404. Tube 400 is one example of a sensor body. The open end 404 is configured to receive the pressure 54 from a process connection 406. A process isolation diaphragm 408 isolates process fluid from the oil filled tube 400. An oil path 410 which can comprise for example, a thin capillary tube extends from the process isolation diaphragm 408 and the tube opening 404. The entire assembly is contained within a housing 414.
As explained below, a quartz sensor 420 (see Figure 6) is mounted to the oil filled tube 400 and has a resonance which changes based upon the applied pressure. The relationship between applied pressure and resonate frequency can be determined through experimentation or other means. The oil filled tube 400 can be considered a cantilever beam. The inside of the oil fill tube is at a higher pressure than the outside. This results in stresses in the tube wall. The tube wall stretches ever so slightly in response to the stress. The quartz crystal is held in contact with tube with two mounts at either end, which were rigidly attached to the tube. The tube wall length changes produce resultant stress in the crystal. Thus resonant frequency of the crystal changes as a function of pressure applied to the tube.
Figure 6 is a simplified circuit diagram of pressure sensing circuitry 411. It is configured to sense a pressure within tube 400 using quartz crystal 420. As illustrated in Figure 6, resonant circuitry 413 couples to the quarts crystal 420 and provides a frequency output to digital converter 415. The resonant circuitry 413 will resonate at a frequency, using known techniques, based upon the stress applied to the quartz crystal 420 from tube 400. This frequency is therefore indicative of the applied pressure. Measurement circuitry 417 is configured to convert the measured frequency to a pressure and provide a pressure output.
In the Figure 7, when a stress is applied, the length of the tube will change by an amount:
ΔL=εLo=FLo/AE=σaLo/E EQ. 1
where E is Young's Modules, ε is strain, F is force, A is area, Lo is the original length of the tube.
The stress in axial direction at a point in the tube wall can be expressed as:
σa =(p1r1 2 - PoToVcΛ-r,2), where EQ. 2 σa= stress in axial direction
P1 = internal pressure in the tube
Po = external pressure in the tube
T1 = internal radius of tube ro = external radius of tube
The hoop stress (circumferential stresses) defined below has twice the magnitude of the axial stress. In order to increase the sensitivity of the sensor the
crystal beam axis is 5 degrees off the tube axis. The purpose is to pick up hoop stresses of the tube. The Stress in Circumferential Direction (Hoop Stress) at a point in the tube wall can be expressed as:
σ
c = [(PiA
2 - p
or
o 2)/(r
o 2 - T
1 2)] + [T
1 2T
0 2
- T
1 2)], where EQ. 3 σ
c= stress in circumferential direction, r = radius to point in tube wall maximum stress when r=ri(inside pipe).
Figure 7 is a diagram showing several resonate vibration modes of a tube. These include longitudinal, translational and sheer modes. The translational mode resonate frequency is inversely proportional to the square of the length. It is analogous to the wagging of a dog's tail and may provide relatively low sensitivity to pressure changes. Similarly, the shear resonance is inversely proportioned to the length and consists of a propagating wave which travels the length of the tube. This also is relatively insensitive to pressure changes. The longitudinal resonate frequency is also inversely proportional to the length and is similar to the resonance of an elongate tube such as a pipe organ. Further, the resonate frequency is also proportionate to the square root of the ratio of tube stiffness divided by the tube mass. This yields a relatively complex relationship as increasing pressure affects both of these terms.
In one configuration, an AT cut crystal is preferred. This configuration is such that forces which cross at the plane of the sensor cause frequency changes similar to, or greater in amplitude to, those produced by other cuts of the crystal. One characteristic of the AT cut is that the resonate frequency is not affected by temperature in an unstressed condition. As the crystal is rigidly mounted, a temperature change will cause stress in the crystal and therefore a change in the resonate frequency. However, the resonate frequency does return to a nominal value as the temperature changes solely due
to differential thermal expansion. Further, crystals with an AT-cut experience large compression forces prior to fracturing and provide a nearly linear force to frequency relationship. This configuration can also oscillate in the thickness (shear mode) and are more rugged than crystals oscillating in other modes. This cut can also respond very rapidly to step changes in stress.
Figures 8A-E show side plan, cross-sectional, front plant, side plan and perspective views of sensor 170 including a quartz crystal structure 420 in accordance with one example embodiment (it can be a single supported beam structure or a triple bar structure). The crystal structure 420 is a triple bar structure in which the central bar vibrates in opposition to the two outer beams. This structure can be clamped at both ends and the entire crystal mounted on a cantilever tube. Electrodes are vacuum deposited on the crystal surface to form the two top surface electrical connections, and a ground plane on the underside of the crystal. In Figures 8A-8E, a pressure sensor assembly 418 is shown. Assembly 418 includes a housing 422 and couples to oil fill tube 400. In the cross-sectional view shown in Figure 8B, the quartz crystal 420 is shown in mounted to tube 400 with crystal mounts 424 and 426 which are arranged at opposed ends of the crystal 420. As illustrated in more clearly in the plan view of Figure 8C, crystal 420 includes electrodes 430 and 432 which extend to a vibrating beam section 434 which is defined between two cut out regions 436 and 438. An electrical ground 440 (shown in Figure 8D) is provided along the backside of crystal 420.
As discussed above, the resonance frequency of the quartz crystal 420 will change as a function of deformation to the tube 400. The fundamental flexural resonance frequency of a rectangular beam anchored at both ends is given by:
where g is the gravitational acceleration constant, E is Young's modulus in the length direction, p is the density of the material, t is the thickness, and 1 is the length between the anchored points. In the structure shown in Figures 20 A-E the fundamental frequency is lower than that shown above because the beams are anchored beyond the points where they are joined and a reduction in fo is to be expected. When a tensile stress is applied along the length of the beam, the fundamental frequency f is given by
4λ where, L ≡ — In one configuration, the oil fill tube can be slightly pre-bent with
a curvature. The total beam curvature change with full scale pressure applied is less than 0.0025 mm. The beam vibrates under fixed end conditions in the vertical plane. The bias frequency is typically 40 kHz, which decreases in response to tube expansion. The oil fill tube acts like a vibration isolation system. The mass of the tube prevents vibration energy from escaping, resulting in high vibration Q. The beam vibrations are sustained by the combination of the piezoelectric properties of quartz crystal, electrodes plated on the beam, and electrical energy provided by an oscillator circuit. The oil fill tube can be straight as shown. The Q factor is proportional to the ratio of the energy stored to energy lost per cycle in the vibration system. The losses are from the change of the rigidity of the pipe that is proportional to the pressure.
Figure 9 shows a cross-sectional view of the quartz tuning fork embodiment. This embodiment uses a quartz crystal tuning fork 450 to detect the pressure in the oil fill tube 400. Quartz crystal tuning fork tactile sensors are
used with robotic fingers to identify an object's physical properties such as hardness, softness, roughness, and smoothness. The material properties beneath the contact surface are identified using a longitudinal mode quartz crystal tuning fork.
The quartz crystal tuning fork 450 comprises a vibration part 458 with a support part (base) 454 that is soldered on the oil fill tube. The quartz crystal tuning fork 450 is allowed to vibrate along the Y axis under the action of the electric field along the X axis. The difference in acoustic impedance between the quartz and the base will cause the longitudinal vibration energy to leak from the sensors base radially to the tube 400. The plane wave is transmitted through the oil and reflected back to the sensor through the oil. The energy leak will let the quartz crystal tuning fork impedance increase at the resonant vibration. Since oil density will vary with pressure, the acoustic energy attenuations will vary. Therefore the acoustic impedance will vary with pressure. At a specific frequency the quartz crystal tuning fork 450 impedance is proportional to the acoustic impedance between the sensor and the oil pressure. Therefore the quartz crystal tuning fork frequency change is proportional to the pressure of the oil in the pipe.
Energy which leaks from the quartz crystal tuning fork base 454 to the tube 400 is dependent upon the contact area of the tube 400 Since the contact area is fixed, the impedance can be measured to identify the oil pressure or the sensor frequency can be compared with a pipe without pressure. The configuration has a number of advantages, including:
• It is small in size these by reducing packaging costs;
• Mechanical components are inexpensive including the quartz structure;
• No pressure header is needed as the measurement is non-intrusive;
• No A/D converter is needed since the signal is frequency based;
• Temperature characterization is simplified because it will be predictable;
• There is little oil movement enabling smaller diaphragms and faster response time;
• Different ranges can be optimized with different tube materials;
• Potential for making very high pressure devices;
• Small size, low cost, and low power.
Differential pressure can be measured using two sensors arranged to sense gauge pressure. The low side differential is connected to one sensor and the high side differential is connected to the other sensor. The electronics simply compares the two frequencies.
Figures 1OA and 1OB show examples of sensor arranged to sense a differential pressure. In Figure 1OA, a cross-sectional view of a tube 480 is shown which includes an orifice plate 482. Orifice plate 482 creates a differential pressure and the flow across the plate. This differential pressure is related to the flow rate. In Figure 1OB, a differential pressure 484 is shown. Sensor 484 includes a first tube 486 coupled to a pressure Pl and a second tube 488 coupled to a pressure P2. A seal 490 separates the tubes 486 and 488. A quartz sensing element 492 couples to tube 486 and a quartz sensing element 494 couples to tube 488. Sensors 492 and 494 operate in accordance with the techniques discussed above. As the differential pressure changes between pressures Pl and P2, the outputs from sensors 492 and 494 will vary accordingly. The difference between the two outputs is related to the differential pressure (P1-P2). In the configuration shown in Figures 1OA and 1OB, the tubes 486 and 488 can be arranged to couple directly to the process fluid. In an alternative embodiment, isolation diaphragms are employed along with a fill fluid.
In other design configurations, a second deformation sensor can be applied to the second fill tube. Using such a configuration, a redundancy check can be provided in which the outputs from the two deformation sensors are compared. Similarly, a differential pressure may be obtained by subtracting the pressure associated with one of the deformation sensors with the pressure associated with the other deformation sensor. Although the deformation sensor discussed herein is illustrated as being associated with the fill tube portion of the capillary tube, the sensor can be located along any appropriate region of the capillary tube and is not limited to this configuration.
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. As used herein, line pressure refers to both absolute and gauge pressure.