Claims
- 1. Apparatus for measuring the mass flow rate of material flowing through at least one vibrating conduit (10), comprising:
- a pair of driving means (D.sub.1, D.sub.2) for imparting differential oscillatory motion at separate points (22, 24) along the conduit (10);
- a pair of motion detectors (P.sub.1, P.sub.2) disposed at separate points (22, 24) along the conduit (10) for detecting motion thereof and for developing first and second motion responsive analog voltage signals (V.sub.1, V.sub.2);
- differencing means (30, U.sub.3) responsive to said first and second analog voltage signals (V.sub.1, V.sub.2) and operative to generate a difference signal (V.sub.3) which is proportional to the voltage difference therebetween;
- summing means (32, U.sub.4) responsive to said first and second analog voltage signals (V.sub.1, V.sub.2) and operative to generate a sum signal (V.sub.4) which is proportional to the sum of the voltages thereof;
- integrating means (34, U.sub.5) for integrating said sum signal (V.sub.4); and
- dividing means (36, U.sub.11 14 U.sub.14, MP) for dividing the integrated sum (V.sub.5) by said difference signal (V.sub.3) to develop an output signal (V.sub.6) proportional to the mass flow rate of material flowing through said conduit (10).
- 2. The apparatus of claim 1, further comprising:
- comparator means (U.sub.6) responsive to said sum signal (V.sub.4) and operative to develop a reference signal; and
- a first lock-in amplifier means (U.sub.7) responsive to said integrated sum signal (V.sub.5) and said reference signal and operative to cause the integrated difference signal input to said dividing means (U.sub.11 -U.sub.14, MP) to be a direct current signal substantially immune to the effects of harmonic distortions produced by mechanical, hydraulic, or electrical characteristics of the preceding signal carrying components.
- 3. The apparatus of claim 2 further comprising:
- a second lock-in amplifier means (U.sub.8) responsive to said difference signal (V.sub.3) and said reference signal and operative to cause the difference signal input to said dividing means (U.sub.11 -U.sub.14, MP) to be a direct current signal substantially immune to the effects of harmonic distortions produced by mechanical, hydraulic, or electrical characteristics of the preceding signal carrying components.
- 4. The apparatus of claim 2, wherein said dividing means (U.sub.11 -U.sub.14, MP) includes:
- a first voltage-to-frequency converter (U.sub.11) for converting said integrated sum signal (V.sub.5) to a corresponding first alternating signal of a first frequency;
- a first counter (U.sub.13) responsive to the frequency of said first alternating signal and operative to generate a first digital signal proportional thereto;
- a second voltage-to-frequency converter (U.sub.12) for converting said difference signal (V.sub.3) to a corresponding second alternating signal of a second frequency;
- a second counter (U.sub.14) responsive to the frequency of said second alternating signal and operative to generate a second digital signal proportional thereto; and
- a processor means (MP) responsive to said first and second digital signals and operative to develop an output signal which is proportional to said first digital signal divided by said s second digital signal.
- 5. The apparatus of claim 3, wherein said dividing means (U.sub.11 -U.sub.14, MP) includes:
- a first voltage-to-frequency converter (U.sub.11) for converting said integrated difference signal (V.sub.5) to a corresponding first alternating signal of a first frequency;
- a first counter (U.sub.13) responsive to the frequency of said first alternating signal and operative to generate a first digital signal proportional thereto;
- a second voltage-to-frequency converter (U.sub.12) for converting said difference signal (V.sub.3) to a corresponding second alternating signal of a second frequency;
- a second counter (U.sub.14) responsive to the frequency of said second alternating signal and operative to generate a second digital signal proportional thereto; and
- a processor means (MP) responsive to said first and second digital signals and operative to develop an output signal which is proportional to said first digital signal divided by said second digital signal.
- 6. The apparatus of claim 1, wherein said dividing means includes:
- a first analog-to-digital converter for converting said integrated sum signal (V.sub.5) to a corresponding first digital signal;
- a second analog-to-digital converter for converting said difference signal (V.sub.3) to a corresponding second digital signal; and
- processor means responsive to said first and second digital signals and operative to develop an output signal which is proportional to said first digital signal divided by said second digital signal.
- 7. Apparatus for measuring the mass flow rate of materials flowing through at least one vibrating conduit (10), comprising:
- a pair of driving means (D.sub.1, D.sub.2) for imparting differential oscillatory motion at separate points (22, 24) along the conduit (10);
- a pair of motion detectors (P.sub.1, P.sub.2) disposed at separate points (22, 24) along the conduit (10) for detecting motion thereof and for developing first and second motion responsive analog voltage signals;
- differencing means (U.sub.3) responsive to said first and second analog voltage signals and operative to generate a difference signal which is proportional to the voltage difference therebetween;
- summing means (U.sub.4) responsive to said first and second analog voltage signals and operative to generate a sum signal which is proportional to the sum of the voltages thereof;
- integrating means for integrating said sum signal;
- first comparator means (U.sub.5) responsive to the integrated sum and operative to develop a first reference signal;
- a first lock-in amplifier means (U.sub.7) responsive to said difference signal and said first reference signal and operative to develop a first direct current signal which is substantially immune to harmonic distortions produced by mechanical, hydraulic, or electrical characteristics of the preceding signal carrying components;
- second comparator means (U.sub.6) responsive to the sum and signal and operative to develop a second reference signal;
- a second lock-in amplifier means (U.sub.8) responsive to said sum signal and said second reference signal and operative to develop a second direct current signal which is substantially immune to harmonic distortions produced by mechanical, hydraulic, or electrical characteristics of the preceding signal carrying components; and
- dividing means for dividing said first direct current signal by said second direct current signal to develop an output signal proportional to the mass flow rate of material flowing through said conduit (10).
- 8. Apparatus for measuring the mass flow rate of material flowing through at least one vibrating conduit (10), comprising:
- a pair of driving means (D.sub.1, D.sub.2) for imparting differential oscillatory motion at separate points (22, 24) along the conduit (10);
- a pair of motion detectors (P.sub.1, P.sub.2) disposed at separate points (22, 24) along the conduit (10) for detecting motion thereof and for developing first and second motion responsive analog voltage signals (V.sub.1, V.sub.2);
- differencing means responsive to said first and second analog voltage signals (V.sub.1, V.sub.2) and operative to generate a difference signal (V.sub.3) which is proportional to the voltage difference therebetween:
- summing means responsive to said first and second analog voltage signals (V.sub.1, V.sub.2) and operative to generate a sum signal (V.sub.4) which is proportional to the sum of the voltage thereof;
- first dividing means for dividing said difference signal (V.sub.3) by said sum signal (V.sub.4) to develop a corresponding first quotient signal (V.sub.5);
- means for developing a frequency signal (w) proportional to the frequency at which said conduit (10) is vibrating; and
- second quotient signal (V.sub.6) which is proportional to the mass flow rate of material flowing through said conduit (10).
- 9. A method of measuring the mass flow rate of material flowing through at least one conduit (10), comprising the steps of:
- causing spaced apart portions of said conduit (10) to oscillate in displacement relative to a rest position and out of phase relative to each other;
- detecting oscillatory motion of at least two separated points (22, 24) along said portions of the conduit (10) and developing corresponding first and second motion responsive analog voltage signals (V.sub.1, V.sub.2) subtracting said first signal (V.sub.2) from said second signal (V.sub.1) to develop a difference signal (V.sub.3) which is proportional to the voltage difference therebetween;
- adding said first and second signals (V.sub.1, V.sub.2) to develop a sum signal (V.sub.4) which is proportional to the sum of the voltages thereof;
- integrating said signal (V.sub.4) to develop an integrated sum signal (V.sub.5); and
- dividing the integrated sum signal (V.sub.5) by said sum signal (V.sub.4) to develop an output signal (V.sub.6) proportional to the mass flow rate of material flowing through said conduit (10).
- 10. The method of claim 9 further comprising the step of synchronously detecting the integrated sum signal (V.sub.5) prior to division by said difference signal (V.sub.3) to remove all signal components not in phase with said sum signal (V.sub.4).
- 11. The method of claim 10 wherein the integrated and synchronously detected difference signal (V.sub.5) and said sum signal (V.sub.4) are digitized and the digitized difference signal is divided by the digitized sum signals to develop said output signal (V.sub.6).
- 12. A method for measuring the mass flow rate of material flowing through at least one conduit (10), comprising the steps of:
- causing spaced apart portions of said conduit (10) to oscillate out of phase with each other and at a frequency (w) relative to a rest position;
- detecting oscillatory motion of the conduit (10) at separate points (22, 24) along said portion of the conduit (10) and developing first and second motion responsive analog voltage signals (V.sub.1, V.sub.2);
- subtracting said first signal (V.sub.2) from said second signal (V.sub.1) to develop a difference signal (V.sub.3) which is proportional to the voltage difference therebetween;
- adding said first and second signals (V.sub.1, V.sub.2) to develop a sum signal (V.sub.4) which is proportional to the sum of the voltages thereof;
- shifting the phase of a signal proportional to said difference signal (V.sub.3) by 90.degree. to develop a reference signal for synchronously detecting said sum signal (V.sub.4) to remove signal components not in phase with said reference signal;
- dividing the detected sum signal by said difference signal (V.sub.3) to develop a corresponding first quotient signal (V.sub.5);
- developing as frequency signal proportional to the frequency (w) at which said conduit (10) is caused to oscillate; and
- dividing said first quotient signal (V.sub.5) by said frequency signal to develop a second quotient signal (V.sub.6) which is proportional to the mass flow rate of material flowing through said conduit (10).
- 13. A method of measuring the mass flow rate of material flowing through at least one conduit (10), comprising the steps of:
- causing spaced apart portions of said conduit (10) to oscillate out of phase with each other and at a frequency relative to a rest position;
- detecting oscillatory motion of said conduit (10) at separate points (22, 24) along said portion of the conduit (10) and developing first and second motion responsive analog voltage signals (V.sub.1, V.sub.2);
- subtracting said first signal (V.sub.2) from said second signal (V.sub.1) to develop a sum signal (V.sub.4) which is proportional to the sum of the voltages thereof;
- dividing said sum signal (V.sub.4) by said difference signal (V.sub.3) to develop a corresponding first quotient signal (V.sub.5);
- developing a frequency signal having a value proportional to the frequency (w) at which said conduit (10) is caused to oscillate; and
- dividing said first quotient signal (V.sub.5) by said frequency signal to develop a second quotient signal (V.sub.6) which is proportional to the mass flow rate of material flowing through said conduit (10).
- 14. The method of claim 13, wherein the integrated sum signal (V.sub.5) and the difference signal (V.sub.3) are analog signals and the step of dividing the two signals (V.sub.3, V.sub.5) is accomplished using an electrical signal processing technique.
Priority Claims (1)
Number |
Date |
Country |
Kind |
88111003.5 |
Jul 1988 |
EPX |
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Parent Case Info
This Application is a Continuation-in-Part of our earlier filed U.S. application Ser. No. 076,512, filed July 22, 1987, now U.S. Pat. No. 4,914,956, issued Apr. 10, 1990.
US Referenced Citations (2)
Number |
Name |
Date |
Kind |
4823614 |
Dahlin |
Apr 1989 |
|
4914956 |
Young et al. |
Apr 1990 |
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Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
76512 |
Jul 1987 |
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