IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0490570
(2002-09-20)
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우선권정보 |
JP-0286557 (2001-09-20) |
국제출원번호 |
PCT/JP02/09679
(2004-03-19)
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§371/§102 date |
20040319
(20040319)
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국제공개번호 |
WO03/02761
(2003-04-03)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Blakely Sokoloff Taylor &
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인용정보 |
피인용 횟수 :
10 인용 특허 :
1 |
초록
▼
When a plane (PLN) which includes electrodes (2a, 2b) and is perpendicular to the direction of an axis (PAX) of a measuring pipe (1) is defined as a boundary in the measuring pipe (1), an exciting coil (3) applies asymmetrical magnetic fields to a fluid to be measured, which flows through the measur
When a plane (PLN) which includes electrodes (2a, 2b) and is perpendicular to the direction of an axis (PAX) of a measuring pipe (1) is defined as a boundary in the measuring pipe (1), an exciting coil (3) applies asymmetrical magnetic fields to a fluid to be measured, which flows through the measuring pipe (1), on both sides of the plane (PLN) serving as the boundary in the measuring pipe (1). A signal conversion unit (5) obtains the phase difference between an exciting current supplied to the exciting coil (3) and an interelectrode electromotive force detected by the electrodes (2a, 2b). A flow rate output unit (6) calculates the flow rate of the fluid on the basis of the phase difference obtained by the signal conversion unit (5).
대표청구항
▼
1. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field changing over time and applied to the fluid and flow of the
1. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field changing over time and applied to the fluid and flow of the fluid; an asymmetrical exciting unit which applies asymmetrical magnetic fields to the fluid on both sides of a plane serving as a boundary in said measuring pipe, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a signal conversion unit which obtains, from an electromotive force detected by said electrode, an asymmetrical exciting characteristic parameter which depends on a flow rate of the fluid and does not depend on a flow rate measurement error; and a flow rate output unit which calculates the flow rate of the fluid for which the flow rate measurement error has been corrected on the basis of the asymmetrical exciting characteristic parameter. 2. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises an exciting coil which is arranged at a position separated from the plane by an offset distance, and a power supply unit which supplies an exciting current to said exciting coil. 3. An electromagnetic flowmeter according to claim 1, characterized in thatsaid signal conversion unit obtains as the asymmetrical exciting characteristic parameter, a phase difference between an exciting current supplied to an exciting coil of said asymmetrical exciting unit and the electromotive force detected by said electrode, and said flow rate output unit calculates the flow rate of the fluid on the basis of the phase difference obtained by said signal conversion unit. 4. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises a first exciting coil which is arranged at a position separated from the plane by an offset distance, a second exciting coil which is arranged at a position different from that of said first exciting coil, and a power supply unit which supplies exciting currents having the same phase to said first exciting coil and said second exciting coil, and in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same phase and different amplitudes on the axis of said electrode. 5. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises a first exciting coil which is arranged at a position separated from the plane by an offset distance, a second exciting coil which is arranged at a position different from that of said first exciting, coil, and a power supply unit which supplies exciting currents to said first exciting coil and said second exciting coil while changing a phase difference between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil, and in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude on the axis of said electrode, and the phase difference between the magnetic field component of said first exciting coil and the magnetic field component of said second exciting coil takes at least two values. 6. An electromagnetic flowmeter according to claim 1, characterized in thatsaid signal conversion unit obtains an amplitude of the electromotive force detected by said electrode for each of at least two states with different phase differences between the exciting currents supplied to said two exciting coils of said asymmetrical exciting unit and obtains a ratio of the amplitudes as the asymmetrical exciting characteristic parameter, and said flow rate output unit calculates the flow rate of the fluid on the basis of the ratio of the amplitudes obtained by said signal conversion unit. 7. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises a first exciting coil which is arranged at a position separated from the plane by an offset distance, a second exciting coil which is arranged at a position different from that of said first exciting coil, and a power supply unit which supplies exciting currents to said first exciting coil and said second exciting coil while continuously switching a phase difference between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil, and in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude on the axis of said electrode, and the phase difference between the magnetic field component of said first exciting coil and the magnetic field component of said second exciting coil continuously switches. 8. An electromagnetic flowmeter according to claim 1, characterized in thatsaid signal conversion unit obtains an amplitude of the electromotive force detected by said electrode for each of a plurality of states with different phase differences between the exciting currents supplied to said two exciting coils of said asymmetrical exciting unit and obtains, as the asymmetrical exciting characteristic parameter, the phase difference for which the amplitude has a predetermined value, and said flow rate output unit calculates the flow rate of the fluid on the basis of the phase difference obtained by said signal conversion unit. 9. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises a first exciting coil which is arranged at a position separated from the plane by an offset distance, a second exciting coil which is arranged at a position different from that of said first exciting coil, and a power supply unit which supplies exciting currents having the same frequency and a predetermined phase difference to said first exciting coil and said second exciting coil while changing the frequency, and in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude, same frequency, and the predetermined phase difference on the axis of said electrode, and the frequency of the magnetic field component switches between at least two values. 10. An electromagnetic flowmeter according to claim 1, characterized in thatsaid signal conversion unit obtains an amplitude of the electromotive force detected by said electrode for each of at least two states in which the frequency of the exciting currents supplied to said two exciting coils of said asymmetrical exciting unit switches and obtains a ratio of the amplitudes as the asymmetrical exciting characteristic parameter, and said flow rate output unit calculates the flow rate of the fluid on the basis of the ratio of the amplitudes obtained by said signal conversion unit. 11. An electromagnetic flowmeter according to claim 1, characterized in thatsaid asymmetrical exciting unit comprises a first exciting coil which is arranged at a position separated from the plane by an offset distance, a second exciting coil which is arranged at a position different from that of said first exciting coil, and a power supply unit which supplies exciting currents having the same frequency and a predetermined phase difference to said first exciting coil and said second exciting coil while continuously switching the frequency, and in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude, same frequency, and the predetermined phase difference on the axis, of said electrode, and the frequency of the magnetic field component continuously switches. 12. An electromagnetic flowmeter according to claim 1, characterized in thatsaid signal conversion unit obtains an amplitude of the electromotive force detected by said electrode for each of a plurality of states in which the frequency of the exciting currents supplied to said two exciting coils of said asymmetrical exciting unit switches and obtains, as the asymmetrical exciting characteristic parameter, the frequency of the exciting current for which the amplitude has a predetermined value, and said flow rate output unit calculates the flow rate of the fluid on the basis of the frequency obtained by said signal conversion unit. 13. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; an exciting coil which is arranged at a position separated from a plane by an offset distance and applies asymmetrical magnetic fields to the fluid on both sides of the plane serving as a boundary in said measuring pipe, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a power supply unit which supplies an exciting current to said exciting coil; a signal conversion unit which obtains a phase difference between the exciting current and an electromotive force detected by said electrode; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the phase difference obtained by said signal conversion unit. 14. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; a first exciting coil which is arranged at a position separated from a plane by an offset distance, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a second exciting coil which is arranged at a position different from that of said first exciting coil; a power supply unit which supplies exciting currents having the same phase to said first exciting coil and said second exciting coil; a signal conversion unit which obtains a phase difference between the exciting current and an electromotive force detected by said electrode; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the phase difference obtained by said signal conversion unit, wherein in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same phase and different amplitudes on the axis of said electrode. 15. An electromagnetic flowmeter according to any one of claims 3, 13, and 14 characterized in thaton the basis of the phase difference φ obtained by said signal conversion unit, said flow rate output unit calculates the flow rate of the fluid by α1×tan(π/2)(α1 is a coefficient). 16. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; a first exciting coil which is arranged at a position separated from a plane by an offset distance, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a second exciting coil which is arranged at a position different from that of said first exciting coil; a power supply unit which supplies exciting currents to said first exciting coil and said second exciting coil while changing a phase difference between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil; a signal conversion unit which obtains an amplitude of the electromotive force detected by said electrode for each of at least two states with different phase differences and obtains a ratio of the amplitudes; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the ratio of the amplitudes obtained by said signal conversion unit, wherein in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude on the axis of said electrode, and the phase difference between the magnetic field component of said first exciting coil and the magnetic field component of said second exciting coil takes at least two values. 17. An electromagnetic flowmeter according to claim 6 or 16, characterized in thatwhen the phase difference between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil takes two values 2χ and 2ψ (χ and ψ are different real numbers), said flow rate output unit calculates, on the basis of a ratio R of the amplitudes obtained by said signal conversion unit, the flow rate of the fluid by α2×{(R sin ψ?sin χ)/(R cos ψ?cos χ)} (θ2 is a coefficient). 18. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; a first exciting coil which is arranged at a position separated from a plane by an offset distance, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a second exciting coil which is arranged at a position different from that of said first exciting coil; a power supply unit which supplies exciting currents to said first exciting coil and said second exciting coil while continuously switching a phase difference between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil; a signal conversion unit which obtains an amplitude of the electromotive force detected by said electrode for each of a plurality of states with different phase differences and obtains the phase difference for which the amplitude has a predetermined value; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the phase difference obtained by said signal conversion unit, wherein in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude on the axis of said electrode and the phase difference between the magnetic field component of said first exciting coil and the magnetic field component of said second exciting coil continuously switches. 19. An electromagnetic flowmeter according to claim 8 or 18, characterized in that on the basis of the phase difference θ2 obtained by said signal conversion unit, said flow rate output unit calculates the flow rate of the fluid by α3×tan(θ2/2) (α3 is a coefficient).20. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; a first exciting coil which is arranged at a position separated from a plane by an offset distance, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a second exciting coil which is arranged at a position different from that of said first exciting coil; a power supply unit which supplies exciting currents having the same frequency and a predetermined phase difference to said first exciting coil and said second exciting coil while changing the frequency; a signal conversion unit which obtains an amplitude of the electromotive force detected by said electrode for each of at least two states with different frequencies and obtains a ratio of the amplitudes; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the ratio of the amplitudes obtained by said signal conversion unit, wherein in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude, same frequency, and the predetermined phase difference on the axis of said electrode, and the frequency of the magnetic field component switches between at least two values. 21. An electromagnetic flowmeter according to claim 10 or 20, characterized in thatwhen the frequency of the exciting currents supplied to said first and second exciting coils switches between two values ω1 and ω2, said flow rate output unit calculates, on the basis of a ratio Ror of the amplitudes obtained by said signal conversion unit, the flow rate of the fluid by α4×{(Rorω2?ω1)sin(θ2/2)}/{(1?Ror)cos(θ2/2)} (α4 is a coefficient). 22. An electromagnetic flowmeter characterized by comprising:a measuring pipe through which a fluid to be measured flows; an electrode which is arranged in said measuring pipe and detects an electromotive force generated by a magnetic field applied to the fluid and flow of the fluid; a first exciting coil which is arranged at a position separated from a plane by an offset distance, the plane including said electrode, being perpendicular to an axial direction of said measuring pipe, and being defined as the boundary in said measuring pipe; a second exciting coil which is arranged at a position different from that of said first exciting coil; a power supply unit which supplies exciting currents having the same frequency and a predetermined phase difference to said first exciting coil and said second exciting coil while continuously switching the frequency; a signal conversion unit which obtains an amplitude of the electromotive force detected by said electrode for each of a plurality of states with different frequencies and obtains the frequency for which the amplitude has a predetermined value; and a flow rate output unit which calculates a flow rate of the fluid on the basis of the frequency obtained by said signal conversion unit, wherein in a magnetic field generated from said first exciting coil and a magnetic field generated from said second exciting coil, magnetic field components which are perpendicular to both of an axial direction of said electrode and the axial direction of said measuring pipe have the same amplitude, same frequency, and the predetermined phase difference on the axis of said electrode, and the frequency of the magnetic field component continuously switches. 23. An electromagnetic flowmeter according to claim 12 or 22, characterized in thaton the basis of the phase difference θ2 between the exciting current supplied to said first exciting coil and the exciting current supplied to said second exciting coil and the frequency ω0 obtained by said signal conversion unit, said flow rate output unit calculates the flow rate of the, fluid by α5×ω0 tan(θ2/2) (α5 is a coefficient). 24. An electromagnetic flowmeter according to any one of claims 1, 13, 14, 16, 18, 20, and 22, characterized in that said electromagnetic flowmeter uses a sine wave exciting method.25. An electromagnetic flowmeter according to any one of claim 1, 13, 14, 16, 18, 20, and 22, characterized in that the number of said electrodes is one.
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