The present invention is concerned with a pressure sensor, a pressure control device and a pressure type flow rate control device to be employed mainly in semiconductor manufacturing facilities, chemical plants and the like, and also concerned with an automatic zero point correction device for the pressure sensor, the pressure control device and the pressure type flow rate control device which has made it possible that the occurrence of measurement errors on the pressure and flow rate due over-time to changes of pressure detection values is prevented by performing an automatic zero point correction in the event that a volume of the change (a drift volume) in the output exceeds the prescribed set value at the time when the output of a pressure sensor to measure fluid pressure changes over time.
With semiconductor manufacturing facilities and chemical products manufacturing facilities, it is required that the flow rate and pressure of raw gases to be supplied are controlled with the high degree of accuracy. To meet the needs, various types of pressure control devices, flow rate control devices and pressure sensors to be employed for these devices have been developed.
Similarly,
With the flow rate control device and the like as described above, it is needed that the gas pressure P1 and the like on the upstream side from the orifice are detected. To detect the pressure, the pressure sensor for which semiconductor pressure sensitive elements such as a strain gauge and the like are used are widely utilized.
It has been known that, with the afore-mentioned pressure sensor to detect the fluid pressure P1, the output values change depending on the environmental conditions surrounding the sensor, for example, such as gas temperature and the like. That is, a pressure sensor placed in the same fluid pressure might have a different output value due to the changes in fluid temperature.
For example, with the aforementioned strain gauge type pressure sensor, pressure is converted to voltage, and the relation that the pressure on the horizontal axis corresponds with the output voltage on the vertical axis on the graph is established. And, the output characteristics that the output voltage reaches zero when the absolute pressure is zero, and the output voltage increases linearly along with the increase of the absolute pressure are desired.
However, it has been known that, with actual the pressure sensor in practicereality, the sensor output changes even under the same gas pressure when in the event that gas temperature changes as described above, and that characteristics of pressure to output have no direct relation to each other in a strict sense.
Concretely, when the pressure applied to the pressure sensor is zero, the sensor output is called a zero point output, while when the zero point changes with temperature changes, it is called a temperature drift of the zero point output, and temperature changes of the sensor output at the time of applying pressure is called a temperature drift of the span output. Adjustments on both the temperature drift of the zero point output and the temperature drift of the span output are needed to obtain an accurate sensor output.
Let's assume, for example, that the zero point voltage is 0(V) without the temperature drift of the zero point output of the pressure sensor, and that the output voltage of the pressure sensor is 20 mV when the absolute pressure of 1.0(×102 kPaA) or the gas pressure of 1 at m is applied to the pressure sensor. When the gas temperature changes under this state, it is anticipated that the output voltage changes from 20 mV. As described above, the change is what is called the temperature drift of the span output. In fact, because of the temperature drift of the zero point output, what changed with the zero point voltage (the zero point output drift) are added to the temperature drift of the span output with any given pressure.
As explained above, with the pressure type flow rate control device and the like wherewith while measuring the upstream side pressure P1 and/or the downstream side pressure P2, a flow rate is controlled when passing through an orifice, there are included errors with the pressure P1, P2 when the output voltage is directly converted to pressure due to the reason that the temperature change characteristics which are a temperature drift of the zero point output and the temperature drift of the span output are included in the output voltage of the pressure sensor.
For this reason, inventors of the present invention have developed system technologies which allow more accurate fluid pressure control, pressure control and flow rate control by automatically correcting the temperature drift of the zero point output and/or the temperature drift of the span output of the pressure sensor caused by the afore-mentioned temperature changes with the control circuits or control software, and made them public in the TOKU-GAN No. 2001-399910.
Techniques pertaining to the afore-mentioned the TOKU-GAN No. 2001-399910 make it possible to almost thoroughly to eliminate control errors on the pressure, flow rate or the like arising from such a temperature drift of the pressure sensor by employing a comparatively simply constituted device, and achieve excellent, practical effects.
However, it has been recently learned that there are existed not only the output voltage changes caused by the afore-mentioned fluid temperature but also the output voltage changes over time with a pressure sensor, particularly with the pressure sensor which employs a semiconductor pressure sensitive element.
The afore-mentioned changes of the output voltage of the pressure sensor over time have become more noticeable when it is used in a state of low pressure (for example, in a vacuum of 10−4˜10−6 Torr to approx. 100 Torr) on the secondary side from the orifice F. Therefore, its influence has not been overlooked with the pressure type flow rate control device which is used for the devices to supply various gases to the process chamber in semiconductor manufacturing facilities.
On the other hand, to eliminate effects due to the afore-mentioned output changes of the pressure sensor over time, it may be possible to formulate a measure where with characteristics of pressure to output of the pressure sensor are slid for a prescribed volume by installing an additional control circuit or a control software. However, it becomes a problem because the additional installation of the device to correct these output changes over time (hereinafter called a time-varying output drift of the pressure sensor) invites a rise in manufacturing costs of a pressure control device or a flow rate control device.
Patent Literature 1: U.S. Pat. No. 5,146,941
Patent Literature 2: TOKU-KAI-HEI No. 8-338546 Public Bulletin
Patent Literature 3: TOKU-KAI-HEI No. 10-82707 Public Bulletin
It is an object of the present invention to solve the afore-mentioned problems with the conventional pressure sensor for which a semiconductor pressure sensitive element is employed or the flow rate/pressure control device for which the pressure sensor is used, namely, (1) that control accuracy of the flow rate, pressure and the like are deteriorated due to changes of the pressure-output characteristics of the pressure sensor over time, (2) that an additional installation of the device to correct the afore-mentioned time-varying output drift invites a rise in manufacturing costs of the pressure control device, a flow rate control device and the like; and to provide an automatic zero point adjustment device for a pressure sensor, a pressure control device and a pressure type flow rate control device which makes possible that the time-varying zero point drift of the pressure sensor is simply and accurately corrected without inviting a substantial rise in production costs by making effective use of a temperature drift correction means for correcting pressure-output characteristics of the pressure sensor equipped with the flow rate/pressure control device.
Inventors of the present invention repeated various kinds of tests as shown below using not only a pressure sensor but also a pressure control device and a pressure type flow rate control device for which the sensor is employed to analyze pressure-output changes of the pressure sensor over time.
With these test results, it has been learned that, with the pressure sensor which employs a semiconductor pressure sensitive element, (1) the zero point of the pressure sensor changes over time, (2) changes of the zero point over time shift toward the minus side without exception when used under vacuum (that is, the output value under pressure zero in the pressure-output characteristics shifts toward the minus side), and (3) the zero point of the pressure sensor shifts toward the minus side, and errors of pressure control accuracy shift toward the plus side for what shifted toward the minus side (that is, if the output value shifts from the zero point toward the minus side under pressure zero, for example, toward the minus side by voltage Δv equivalent to 0.2% of the full scale output voltage, errors of pressure control accuracy rise by voltage_Δv equivalent to 0.2% of the full scale output voltage).
The present invention has been created based on the knowledge obtained from what learned as above. The present invention as claimed in Claim 1 is fundamentally so constituted that, with a pressure sensor to measure fluid pressure, the output voltage from the pressure sensor is outputted to the outside, the afore-mentioned sensor output voltage is inputted to the time-varying zero point drift correction means of the pressure sensor, a judgment is made to determine if the afore-mentioned sensor output voltage is larger than the set value with the said sensor output judgment means of the time-varying zero point drift correction means, and further the operating conditions of the pressure sensor are judged with the afore-mentioned operating condition judgment means of the time-varying zero point drift correction means, the time-varying zero point drift of the pressure sensor is cancelled when it is found that the afore-mentioned sensor output voltage is larger than the set value and the operating conditions of the pressure sensor are under the operating conditions previously set.
The present invention as claimed in Claim 2 according to Claim 1 is fundamentally so constituted that a semiconductor pressure sensitive element is employed for a pressure sensor, the output voltage from the pressure sensor is outputted to the outside through the amplifier and is inputted to the time-varying zero point drift correction means of the pressure sensor through an A/D converter, and further the output for the zero point correction, which is identical to the afore-mentioned sensor output voltage and with reversed polarity, is inputted to the offset terminal of the afore-mentioned amplifier from the afore-mentioned time-varying zero point drift correction means through the D/A converter when the sensor output voltage is larger than the set value and the pressure sensor is under the set operating conditions.
The present invention as claimed in Claim 3 is fundamentally so constituted that, with the pressure control device equipped with a control valve for pressure control and a pressure sensor to measure fluid pressure, the output voltage from the pressure sensor is outputted to the outside, the afore-mentioned sensor output voltage is inputted to the time-varying zero point drift correction means of the pressure sensor, a judgment is made to determine if the afore-mentioned sensor output voltage is larger than the set value with the said sensor output judgment means of the time-varying zero point drift correction means, and further the operating conditions of the pressure sensor are judged with the afore-mentioned operating condition judgment means of the time-varying zero point correction means, the time-varying zero point drift of the pressure sensor is cancelled when it is found that the afore-mentioned sensor output voltage is larger than the set value and the operating conditions of the pressure sensor are under the operating conditions previously set.
The present invention as claimed in Claim 4 according to Claim 3 is fundamentally so constituted that a semiconductor pressure sensitive element is employed for a pressure sensor, the output voltage from the pressure sensor is outputted to the outside through the amplifier and is inputted to the time-varying zero point drift correction means of the pressure sensor through an A/D converter, and further the output for the zero point correction, which is identical to the afore-mentioned sensor output voltage and with reversed polarity, is inputted to the offset terminal of the afore-mentioned amplifier from the afore-mentioned time-varying zero point drift correction means through the D/A converter when the sensor output voltage is larger than the set value and the pressure sensor is under the set operating conditions.
The present invention as claimed in Claim 5 is fundamentally so constituted with the pressure type flow rate control device comprising an orifice for the flow rate control, a control valve mounted on the upstream side pipe from the orifice, and an upstream side pressure sensor installed between the orifice and the control valve to detect upstream side pressure P1 to control the flow rate of fluid passing through the orifice by the upstream side pressure P1, the afore-mentioned output voltage from the pressure sensor is outputted to the flow rate computing means, the afore-mentioned sensor output voltage is inputted to the time-varying zero point drift correction means of the pressure sensor, a judgment is made to determine if the afore-mentioned sensor output voltage is larger than the set value with the said sensor output judgment means of the time-varying zero point drift correction means, and further the operating conditions of the pressure sensor are judged with the afore-mentioned operating condition judgment means of the time-varying zero point correction means, the time-varying zero point drift of the pressure sensor is cancelled when it is found that the afore-mentioned sensor output voltage is larger than the set value and the operating conditions of the pressure sensor are under the operating conditions previously set.
The present invention as claimed in Claim 6 according to Claim 5 is fundamentally so constituted that a semiconductor pressure sensitive element is employed for a pressure sensor, the output voltage from the pressure sensor is outputted to the outside through the amplifier and is inputted to the time-varying zero point drift correction means of the pressure sensor through an A/D converter, and further the output for the zero point correction, which is identical to the afore-mentioned sensor output voltage and with revered polarity, is inputted to the offset terminal of the afore-mentioned amplifier from the afore-mentioned time-varying zero point drift correction means through the D/A converter when the sensor output voltage is larger than the set value and the pressure sensor is under the set operating conditions.
The present invention as claimed in Claim 7 is fundamentally so constituted with the pressure type flow rate control device comprising an orifice for the flow rate control, a control valve mounted on the upstream side pipe from the orifice, an upstream side pressure sensor installed between the orifice and the control valve to detect upstream side pressure P1, and a downstream side pressure sensor mounted on the downstream side pipe to detect downstream side pressure P2 to control the flow rate of fluid passing through the orifice by both upstream side pressure P1 and downstream side pressure P2, the output voltage from the pressure sensor is outputted to the flow rate computing means, the afore-mentioned sensor output voltage is inputted to the time-varying zero point drift correction means of the pressure sensor, a judgment is made to determine if the afore-mentioned sensor output voltage is larger than the set value with the said sensor output judgment means of the time-varying zero-point drift correction means, and further the operating conditions of the pressure sensor are judged with the afore-mentioned operating condition judgment means, the time-varying zero point drift of the pressure sensor is canceled when it is found that the afore-mentioned sensor output voltage is larger than the set value and the operating conditions of the pressure sensor are under the operating conditions previously set.
The present invention as claimed in Claim 8 according to Claim 7 is fundamentally so constituted that a semiconductor pressure sensitive element is employed for a pressure sensor, the output voltage from the pressure sensor is outputted to the outside through the amplifier and is inputted to the time-varying zero point drift correction means of the pressure sensor through an A/D converter, and further the output for the zero point correction, which is identical to the afore-mentioned sensor output voltage and with reversed polarity, is inputted to the offset terminal of the afore-mentioned amplifier from the afore-mentioned time-varying zero-point drift correction means through the D/A converter when the sensor output voltage is larger than the set value and the pressure sensor is under the set operating conditions
The present invention as claimed in Claim 9 according to Claim 3 or Claim 4 is so made that the set value as a reference at the sensor output judgment means of the time-varying zero point drift correction means of the pressure sensors becomes the sensor output voltage equivalent to less than control accuracy of the full scale pressure FS to be detected by the pressure sensor.
The present invention as claimed in Claim 10 according to Claim 3 or Claim 4 is so made that the set operating conditions as a reference at the operating condition judgment means of the time-varying zero point drift correction means of the pressure sensor are made up of three conditions, that is, whether or not a signal for forced opening to the control valve exists, whether or not a signal for forced closing to the control valve exists, and the set signal for the flow rate is zero.
The present invention as claimed in Claim 11 according to Claim 5, Claim 6, Claim 7 or Claim 8 is so made that the set value as a reference at the sensor output judgment means of the time-varying zero point drift correction means of the pressure sensor becomes the sensor output voltage equivalent to less than control accuracy of the full scale pressure FS to be detected by the pressure sensor.
The present invention as claimed in Claim 12 according to Claim 5, Claim 6, Claim 7 or Claim 8 is so made that the set operating conditions as a reference at the operating condition judgment means of the pressure sensor are made up of three conditions, that is, whether or not a signal for forced opening to the control valve exists, whether or not a signal for forced closing to the control valve exists, and the set value of the flow rate is zero.
The present invention as claimed in Claim 13 according to Claim 4 is so made that a D/A converter, through which voltage for the zero point correction is outputted to the offset terminal of the amplifier from the time-varying zero point correction means, is shared with the temperature drift correction means of the pressure sensor mounted on the flow rate computing means of the said pressure type flow rate control device.
The present invention as claimed in Claim 14 according to Claim 6 or Claim 8 is so constituted that a D/A converter, through which voltage for the zero point correction is outputted to the offset terminal of the amplifier from the time-varying zero point drift correction means, is shared with the temperature drift correction means of the pressure sensor mounted on the flow rate computing means of the said pressure type flow rate control device.
According to the present invention as claimed in Claim 1, is constituted so the zero point drift which occurs with changes over-time is cancelled based on judgment by the time-varying zero point drift correction means, thus resulting in substantial improvements in pressure detection accuracy of the pressure sensor.
According to the present invention as claimed in Claim 2, it is so constituted that the zero point drift which occurs with changes over time is cancelled by inputting voltage, which is identical to the drift voltage occurred with changes over time of the pressure sensor and with reversed polarity, to the offset terminal of an amplifier for amplifying output of the pressure sensor based on the judgment by the time-varying zero point drift correction means, thus resulting in substantial improvements in pressure detection accuracy of the pressure sensor.
Also according to the present invention as claimed in Claim 3 to Claim 8 inclusive, control accuracy of pressure and flow rate is remarkably improved due to the reason that pressure detection accuracy of the pressure sensor which functions as the basis of pressure control and flow rate control is enhanced.
According to the present invention as claimed in Claim 9 and Claim 11, an automatic zero point correction is conducted based on the sensor output voltage less than control accuracy of the full scale pressure FS to be detected by the pressure sensor, for example, that equivalent to 0.13% of the full scale FS, thus always allowing the flow rate measurement value to be maintained within the prescribed range of accuracy.
Furthermore, according to the present invention as claimed in Claim 10 and Claim 12, the zero point drift can be cancelled with the high degree of accuracy due to the reason that the time-varying zero point drift correction is automatically performed in the event that the environmental conditions surrounding the pressure sensor on the upstream side from the orifice are in a state of the near-vacuum.
According to the present invention as claimed in Claim 13 and Claim 14, a D/A converter to supply voltage for the drift correction to the offset terminal of an amplifier is made in such a manner that it is shared with the temperature drift correction means of the pressure sensor, thus allowing the constitutions of the correction means of the temperature drift and the time-varying drift of the pressure sensor for the pressure control device and the pressure type flow rate control device to be simplified. As stated above, the present invention achieves excellent, practical effects.
First, inventors of the present invention conducted a survey and then measured changes over-time of pressure-output characteristics of a pressure sensor A by fixing the pressure sensor A structured as shown in
Referring to
Referring to
Though not illustrated in
Gas pressure P1 applied to a diaphragm 23 changes by decompressing the inside of the pipe B, and accordingly pressure applied to the sensor chip 22 (or a strain gauge) changes, thus resulting in changes in the output voltage from the sensor chip 22, and changes in gas pressure P1 is detected. Because the pressure sensor A itself is publicly disclosed (the TOKU-KAI-HEI No. 10-82707 and others), the explanation is omitted herewith.
As apparent from
The output of the pressure sensor on the vertical axis in
As apparent from
Apparent from
With the result in
From the test results shown in
1. With the cycle test of vacuum maintaining, vacuum60 Torr, the zero point keeps changing toward the minus direction.
2. With vacuum maintaining, prominent changes are shown in the initial few hours.
3. Though the percentage of change decreases with the lapse of time, it is found that relatively large changes are seen in the initial stage when it is returned to atmospheric pressure or it is evacuated after it was put in a state of being pressurized to 0.1 MPaG.
4. Unevenness is seen in the vacuum60 Torr cycle test. With some, it is found that the volume of changes is larger than that in the test of vacuum maintaining. After the lapse of one week, it is found that some are out of 0.2% FS.
5. It is assumed that from the results of 0.1 MPaG maintaining test, the zero point does not change with this much pressurization maintaining. It is also understood that there are not big changes when it is in a state of atmospheric pressure.
Based on the changes over-time in the zero point output of the pressure sensor A as stated above, inventors of the present invention have created a measure to automatically correct the over-time changes in the zero point not only of the pressure sensor A, but also of the pressure control device and the pressure type flow rate control device which employ the pressure sensor A.
An automatic zero point adjustment device to correct changes over-time in the zero point output of the pressure type flow rate control device according to the present invention is explained hereafter with reference to the drawings.
A control circuit 7, which is constituted centering around an electronic circuit, a micro-computer and a built-in program, comprises an electronic circuit system such as an amplification circuit not illustrated, an A/D converter and the like, a flow rate computing means 7a to compute a flow rate Qc using the experimental flow rate equation, a flow rate setting means 7b to command the set flow rate Qs to flow, and a comparative means 7c to compute the flow rate difference ΔQ (=Qs−Qc or Qc−Qs) between the flow rate Qc to be computed and the set flow rate Qs.
Referring to
Pressure P2 on the downstream side from the orifice 2 is set considerably smaller than pressure P1 on the upstream side by evacuation using a vacuum pump, automatically to hold the critical condition of P2/P1< approximately 0.5 at any time. As a result, the velocity of the gas to flow out through the orifice opening becomes that of sound, and the flow rate Q passing through the orifice 2 is expressed as Q=KP1.
Pressure P1 on the upstream side is measured by the pressure sensor 3. For the accurate measurement of pressure, the sensor part of the pressure sensor 3 is brought into contact with the gas flow. Furthermore, the sensor part is designed to be minimal so that the gas flow can stay out of turbulence. Accordingly, temperature of the sensor part becomes equal to gas temperature T.
Gas temperature T is measured by the temperature sensor 6. Temperature in the proximity of the orifice 2 is measured by the temperature sensor 6 so that the gas flow can stay out of turbulence. When both the gas and the orifice reach a state of equilibrium, thermally, their temperature becomes equal. Therefore, temperature of the orifice can be measured as that of the gas.
Pressure P1 on the upstream side and temperature T of the gas are provided as voltage, and turned to be digital signals by the amplification circuit or the A/D converter. The digital signals are inputted to the flow rate computing means 7a, and proportional coefficient K is computed from the gas temperature
T and gas properties, and the flow rate Qc to be computed by the equation Qc=KP1 by making use of pressure P1 on the upstream side.
The set flow rate Qs has been inputted from the flow rate setting means 7b, and thus, the flow rate ΔQ is computed with equation ΔQ=Qs−Qc by the comparative means 7c.
Computed flow rate difference ΔQ is outputted to the valve driving part 8, and the degree of opening of the control valve 9 is adjusted to make ΔQ zero. With the opening adjustment, pressure P1 on the upstream side from the orifice is variably adjusted, thus the flow rate Qc to be computed and obtained with the equation Qc=KP1 being controlled to be equal to the set flow rate.
As stated above, temperature of the sensor part of the pressure sensor 3 is made to be equal to gas temperature T, and temperature of the sensor part of the pressure sensor changes as gas temperature changes. And, the pressure sensor 3 has temperature dependency so that the output voltage of the pressure sensor changes as temperature changes. Accordingly, the pressure type flow rate control device according to the present invention is equipped with a device to correct changes (drift) of the output voltage caused by temperature with the pressure sensor 3 as shown in
Referring to
Assuming that 100 mV is outputted at the time when the afore-mentioned pressure sensor 3 perceives absolute pressure P1=7 atmospheric pressure (that is, 7×102 kPaA), output voltage V of the pressure sensor 3 becomes output voltage in the range of V=0˜42.86 V when pressure P1 on the upstream side is controlled in the range of P1=0˜3(×102 kPaA) by the pressure sensor.
If the maximum voltage 42.86 mV of output voltage V is amplified to the full scale of 5V, the amplification rate becomes 117 times. With this embodiment, a 117-times amplification rate has been realized by making 100 times with the afore-mentioned fixed amplifier 16 and 1.17 times with the variable amplifiers 17, 18.
Output voltage of the pressure sensor 3 drifts with temperature changes. Output changes (drift) at zero pressure is called a zero point output temperature drift, and output changes (drift) under any given pressure is called an output temperature drift.
The afore-mentioned zero point output temperature drift is corrected by adjusting the offset terminal 16a of the fixed amplifier 16. Concretely, correction of the zero point output drift is realized by the D/A converter for offsetting. That is, when output voltage V indicates a certain value +v0 at the time of pressure zero, −v0 is inputted to the offset terminal 16a, to make the zero point output drift voltage zero. As a result, changes (drift) in the zero point output have been corrected as effective input voltage becomes v0+(−v0)=0 even when output voltage v0 is inputted to the fixed amplifier 16 at pressure zero.
The afore-mentioned D/A converter for offsetting comprises a D/A converter 40a for coarse adjustment and a buffer 40c, a D/A converter 40b for fine adjustment and a buffer 40d, and a buffer 40e for synthesis. As explained herewith, the zero point output drift is corrected by canceling the zero point output drift by means of applying the zero point correction voltage −v0, for which the zero point output drift voltage v0 is reversed, to the offset terminal 16a by the circuit for coarse adjustment and the circuit for fine adjustment.
Thus, a dotted line a′ connecting v0 and v1 in
Next, the full scale setting of the pressure sensor 3 is performed. When the output of the pressure sensor after the zero point adjustment is 0˜v1+ (−v0), that is, 0˜43.8 mV, it is set to the full scale 5V. That is, to amplify 42.8 mV to 5V, the amplification rate of the variable amplifiers 44, 46 is made to be 1.17. As the result, the 2-step amplification rate is set at M=100×1.17=117. This correction is shown by the arrow 6.
Accordingly, the maximum voltage Vm becomes Vm=(v1−v0), and the output voltage v of the pressure sensor 3 at any given pressure P1 is amplified to V=M(v−v0). The solid line C represents the amplified output V. For the critical condition, V=a(T0)P1 is represented by the solid line C. The proportional constant a(T0) shows the proportional constant when gas temperature T is T0.
With the explanation on the afore-shown
On the other hand, with the present invention, the issue is the zero point correction of the over-time changes of the output v of the pressure sensor. Therefore, by defining that the zero point output drift v0 in the afore-shown
That is, it can be grasped that the straight line a′ with the afore-shown
Detailed explanation on how to measure the over-time output change characteristics of the output v of the pressure sensor 3 illustrated in the afore-shown
The afore-shown
With the present invention, it is made in such a manner that when the time-varying zero point output drift v0 of the pressure sensor 3 becomes larger than −0.13% FS (that is, the zero point output drift v0 of −2.6 mV), an automatic zero point adjustment of the pressure sensor 3 is performed by applying the zero point output drift v0 to the offset terminal 16a of the fixed amplification circuit 16 shown in
The reasons why the afore-mentioned −0.13% FS is made to be an adjusting reference point for the time-varying zero point drift are that, after the result of the basic tests shown in
Concretely, first, a judgment is made to see whether or not the output voltage v of the pressure sensor 3 is on the minus side.
It should be noted that gas pressure has always been applied to the pressure sensor 3 while a pressure control device is in use. This means that there is no chance that the output voltage v of the pressure sensor 3 is on the minus side. Accordingly, when it is judged that the output voltage v of the pressure sensor 3 is on the minus side, it is known that the pressure control device is not in use, and that no gas is running.
When maintained under vacuum, it is certain that the time-varying zero point output voltage drift of the pressure sensor 3 is always on the minus side. Therefore, it is understood that the pressure sensor 3 is maintained under vacuum or near-vacuum (of the order of 10−2˜10−6 Torr) if the output drift v of the pressure sensor 3 is found on the minus side.
Accordingly, by judging that the output voltage drift v of the pressure sensor 3 is on the minus side, the adjustment of the time-varying zero point drift can be performed anytime because it tells that the pressure type flow rate control device is in a state of no use, and the pressure inside the pipe is maintained in near-vacuum.
Next, a judgment is made to find if the output voltage drift v of the pressure sensor 3 exceeds the afore-mentioned set value (v=−0.13% FS) or not. And, in case that it is found that the output drift v of the pressure sensor exceeds the set value, the adjustment of the zero point drift v0 is automatically performed with the self-test wherein it is judged that the adjustment of the time-varying zero point drift of the pressure sensor 3 is required.
The control circuit of the pressure type flow rate control device is also nearly the same as that in
With
The time-varying zero point drift correction means 49 of the pressure sensor is equipped with a means to judge if the input value v from the A/D converter 44 exceeds the set value (−0.13% FS=−2.6 mV) (a sensor output judgment means 49a), and an operating condition judgment means 49b to judge either if the input for forced closing to a control valve 9 is set or if the pressure setting signal V is less than 0.6% FS. When one of the following occurs, that is, (1) if input for forced opening of the control valve 9 is set, (2) if input for forced closing of the control valve 9 is set, or (3) if the pressure setting signal V is less than 0.6% FS (V=60 mV·sensor output voltage v=12 mV) is confirmed, and also when it is confirmed that output v of the pressure sensor 3 is more than −0.13% FS by the sensor output judgment means 49a, then voltage for the zero point adjustment (v0=2.6 mV), which is equivalent to +0.13% FS, is automatically inputted to the offset terminal 16a of the fixed amplification circuit 16 from the D/A converter, thus performing the automatic zero point adjustment by the drift output (−2.6 mV) equivalent to the time-varying zero point drift (−0.13% FS) of the pressure sensor being canceled therewith.
Lastly, with the step m5, when v exceeds −12 mV and either one of the conditions Vc>0 or V0>0, or V<0.6% FS is satisfied (step m5), then output voltage of +v(=2.6 mV) is outputted to the offset terminal 16a of the fixed amplification circuit 16 with the step m6.
With the embodiment according to the present invention illustrated in the afore-shown
Feasibility of the Industrial Use
The present invention is mainly used for semiconductor manufacturing facilities or chemical products manufacturing facilities. The present invention is also widely used in the fields where the high degree of accuracy is required to control the flow rate or the supply pressure of fluids such as raw gases.
Number | Date | Country | Kind |
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2003-177135 | Jun 2003 | JP | national |
This is a National Phase Application in the United States of International Patent Application No. PCT/JP2004/008118 filed Jun. 10, 2004, which claims priority on Japanese Patent Application No. 2003-177135, filed Jun. 20, 2003. The entire disclosures of the above patent applications are hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP04/08118 | 6/10/2004 | WO | 3/6/2007 |