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    • 23. 发明申请
    • METHOD FOR DETERMINING THE VISCOSITY OF A MEDIUM WITH A CORIOLIS MASS FLOWMETER
    • 用CORIOLIS质量流量计测定介质粘度的方法
    • US20120048034A1
    • 2012-03-01
    • US12912157
    • 2010-10-26
    • Yousif HUSSAINTao WANG
    • Yousif HUSSAINTao WANG
    • G01F1/84
    • G01F1/8495G01F1/8409
    • A method for determining the viscosity of a medium with a Coriolis mass flowmeter, wherein the Coriolis mass flowmeter has at least two measuring tubes that medium can flow through and a measuring device, wherein the measuring device has at least two actuator assemblies, wherein a measuring tube plane is defined by the measuring tube central axis and wherein the actuator assemblies are arranged on both sides of the measuring tube plane and outside of the measuring tube plane. Elaborate constructional measures for the Coriolis mass flowmeter are avoided by the measuring tubes being excited with a measuring device to at least oppositely directed torsion oscillation (and optionally additionally to plane oscillation) with the actuator assemblies being alternately actuated with opposing effective directions so that at least the viscosity of the medium is determined by evaluation of values from the measuring device.
    • 用科里奥利质量流量计确定介质粘度的方法,其中科里奥利质量流量计具有至少两个介质可以流过的测量管和测量装置,其中测量装置具有至少两个致动器组件,其中测量 管面由测量管中心轴限定,其中致动器组件布置在测量管平面的两侧和测量管平面的外侧。 通过用测量装置激发测量管至少相反方向的扭转振荡(并且可选地平面振荡),可以避免科里奥利质量流量计的精确结构措施,致动器组件以相反的有效方向交替致动,使得至少 通过评估来自测量装置的值来确定介质的粘度。
    • 25. 发明申请
    • Method for processing a time discrete, one dimensional, measurement signal
    • 用于处理时间离散的一维测量信号的方法
    • US20110257906A1
    • 2011-10-20
    • US13085807
    • 2011-04-13
    • Rémy Scherrer
    • Rémy Scherrer
    • G06F19/00G01F1/78
    • G01F1/8409G01D1/16G01F1/8431G01F1/8436
    • A method for processing a time discrete, one dimensional, measurement signal. The method includes the step of applying to the sequence a recursive filter having a variable recursion coefficient (K(n)), wherein the recursive filter is embodied in such a manner that, in each case, the output, measured value (y(n)) obtained for a measured value (x(n)) is obtainable by subtracting a preceding output, measured value (y(n−1)) from such measured value (x(n)), by multiplying the obtained difference value (d(n)) with a recursion coefficient (K(n)) associated with such measured value (x(n)) and by adding the obtained product to the preceding output, measured value (y(n−1)). For determining the recursion coefficient (K(n)) associated with a measured value (x(n)), a predetermined function (Klin(da)) rising at least sectionally with the magnitude of the difference value (da) is applied to the magnitude (da(n)) of the difference value (d(n)) obtained for such measured value and the obtained function value (Klin(n)) is applied recursion coefficient (K(n)) as corresponding to such measured value x(n), at least when the function value (Klin(n)) is greater than or equal to the recursion coefficient associated with the preceding measured value (K(n−1)).
    • 一种用于处理时间离散的一维测量信号的方法。 该方法包括向序列应用具有可变递归系数(K(n))的递归滤波器的步骤,其中递归滤波器以这样的方式实现:在每种情况下,输出,测量值(y(n 通过将得到的差值(d(n))乘以从该测定值(x(n))中减去前一输出,测定值(y(n-1)), (n)),并将所得到的乘积加到前一个输出,即测量值(y(n-1))。 为了确定与测量值(x(n))相关联的递归系数(K(n)),将至少与差值(da)的大小区分上升的预定函数(Klin(da))应用于 对于这样的测量值获得的差值(d(n))的幅度(da(n))和所获得的函数值(Klin(n))被应用为与这样的测量值x相对应的递归系数(K(n)) (n)),至少当函数值(Klin(n))大于或等于与先前测量值(K(n-1))相关联的递归系数时)。
    • 26. 发明申请
    • Measuring transducer of vibration-type, as well as an in-line measuring device having such a measuring transducer
    • US20110146416A1
    • 2011-06-23
    • US12659531
    • 2010-03-11
    • Ennio BittoAlfred RiederMartin AnklinChristof Huber
    • Ennio BittoAlfred RiederMartin AnklinChristof Huber
    • G01F1/84
    • G01F1/8495G01F1/8409G01F1/8413G01F1/8431G01F1/8436G01F15/024G01N11/16
    • The measuring transducer serves for registering at least one physical, measured variable of a flowable medium guided in a pipeline and/or for producing Coriolis forces serving for registering a mass flow rate of a flowable medium guided in a pipeline. For such purpose, the measuring transducer comprises: A transducer housing (71), of which an inlet-side, housing end is formed by means of an inlet-side, flow divider (201) having exactly four flow openings (201A, 201B, 201C, 201D) spaced, in each case, from one another and an outlet-side, housing end is formed by means of an outlet-side, flow divider (202) having exactly four flow openings (202A, 202B, 202C, 202D) spaced, in each case, from one another; as well as exactly four, straight, measuring tubes (181, 182, 183, 184) connected to the flow dividers (201, 202) for guiding flowing medium along flow paths connected in parallel. Each of the four measuring tubes opens with an inlet-side, measuring tube end into one the flow openings (201A, 201B, 201C, 201D) of the inlet-side, flow divider (201) and with an outlet-side, measuring tube end into one the flow openings (202A, 202B, 202C, 202D) of the outlet-side, flow divider (202). Additionally, the measuring transducer includes an electromechanical exciter mechanism (5) for producing and/or maintaining mechanical oscillations of the four measuring tubes (181, 182, 183, 184), wherein the exciter mechanism is embodied in such a manner, that, therewith, the measuring tubes are excitable pairwise to execute opposite phase bending oscillations in, in each case, a shared imaginary plane of oscillation (XZ1, XZ2). The measuring transducer of the invention is suitable, especially, for measuring a density and/or a mass flow rate of a medium flowing in a pipeline, at least at times, with a mass flow rate of more than 2200 t/h.
    • 27. 发明申请
    • Vibration-type measuring transducer as well as measuring device with such a measuring transducer
    • 振动型测量传感器以及带测量传感器的测量装置
    • US20110023624A1
    • 2011-02-03
    • US12805252
    • 2010-07-21
    • Christof HuberVivek KumarChristian Schütze
    • Christof HuberVivek KumarChristian Schütze
    • G01F1/84
    • G01F1/8477G01F1/8409G01F1/8431
    • A measuring transducer comprising at least one measuring tube for conveying a flowing medium. The measuring tube vibrates at least at times during operation. A sensor arrangement, which serves to register oscillations of the at least one measuring tube. The measuring tube extends with an oscillatory length between an inlet-side, first measuring tube end, and an outlet-side, second measuring tube end, and, during operation, oscillates about an oscillation axis, which is parallel to or coincides with an imagined connecting axis which imaginarily connects the two measuring tube ends. By means of a first oscillation sensor, the sensor arrangement produces a first primary signal of the measuring transducer representing vibrations of the measuring tube, and by means of a second oscillation sensor the sensor arrangement produces a second primary signal of the measuring transducer representing vibrations of the measuring tube, wherein a length of a region of the first measuring tube extending between the first oscillation sensor and the second oscillation sensor defines a measuring length of the measuring transducer. The oscillation sensors of the sensor arrangement are placed in the measuring transducer in such a way that a measuring transducer sensitivity, SACT, referenced to a theoretical sensitivity at a maximum measuring length corresponding to the oscillatory length, as well as a signal amplitude, of the primary signals actually achieved during operation, referenced to a theoretically maximum possible signal amplitude, AMAX, at the location of maximum oscillation amplitude, fulfill the condition  = A ACT A MAX · S ACT S MAX  = !  Max .
    • 一种测量传感器,包括用于传送流动介质的至少一个测量管。 至少在操作过程中,测量管至少会振动。 传感器装置,其用于记录至少一个测量管的振荡。 测量管以入口侧,第一测量管端和出口侧,第二测量管端之间的振荡长度延伸,并且在操作期间围绕摆动轴振荡,该振荡轴与想象的平行或重合 连接轴,其连接两个测量管端。 通过第一振动传感器,传感器装置产生表示测量管振动的测量传感器的第一主信号,并且借助于第二振荡传感器,传感器装置产生测量传感器的第二主信号,其表示振动 所述测量管,其中在所述第一振动传感器和所述第二振动传感器之间延伸的所述第一测量管的区域的长度限定所述测量换能器的测量长度。 传感器装置的振荡传感器被放置在测量传感器中,使得测量传感器灵敏度SACT以与振荡长度相对应的最大测量长度的理论灵敏度以及信号幅度参考 在运行期间实际实现的主信号,参考理论上最大可能的信号幅度AMAX,在最大振荡幅度的位置,满足条件= A ACT A MAX·S ACT S MAX = 最大
    • 29. 发明授权
    • Coriolis flowmeter having a fixing member with non-parallel inlet and outlet portions
    • 科里奥利流量计具有具有非平行入口和出口部分的固定构件
    • US07739920B2
    • 2010-06-22
    • US10585939
    • 2004-09-24
    • Hirokazu KitamiYuichi NakaoNorio Sukemura
    • Hirokazu KitamiYuichi NakaoNorio Sukemura
    • G01F1/84
    • G01F1/8409G01F1/8413G01F1/8477G01F1/8486G01N2009/006
    • A first inlet portion, a second inlet portion, a first outlet portion, and a second outlet portion are fixed to a fixing member, and a connecting tube portion is provided between the first outlet portion and the second inlet portion. Further, the first inlet portion and the second inlet portion 6 are arranged in a non-parallel state such that the distance between the two increases as they depart from the fixing member. The first outlet portion and the second outlet portion are similarly arranged in a non-parallel state, the first inlet portion and the second inlet portion and the first outlet portion and the second outlet portion being arranged symmetrically. Further, the first outlet portion, the second inlet portion, and the connecting tube portion are arranged such that their three tube axes are in a straight line.
    • 第一入口部分,第二入口部分,第一出口部分和第二出口部分固定到固定部件上,并且连接管部分设置在第一出口部分和第二入口部分之间。 此外,第一入口部分和第二入口部分6布置成非平行状态,使得它们之间的距离随着离开固定构件而增加。 第一出口部分和第二出口部分类似地布置成非平行状态,第一入口部分和第二入口部分以及第一出口部分和第二出口部分对称地布置。 此外,第一出口部分,第二入口部分和连接管部分被布置成使得它们的三个管轴线成直线。
    • 30. 发明授权
    • Measuring transducer of the vibration-type with two cantilevers
    • 用两个悬臂测量振动型传感器
    • US07658116B2
    • 2010-02-09
    • US12003105
    • 2007-12-20
    • Alfred RiederMichael FuchsLeonhard ProbstMichael Wiesmann
    • Alfred RiederMichael FuchsLeonhard ProbstMichael Wiesmann
    • G01F1/84
    • G01F1/849G01F1/8409G01F1/8413G01F1/8418G01F1/8422G01F1/8427G01F15/024
    • A measuring transducer includes: A measuring tube vibrating, at least at times, during operation and serving for conveying a medium, wherein the measuring tube communicates with a pipeline via an inlet tube piece at an inlet end and an outlet tube piece at an outlet end; a counteroscillator, which is affixed to the measuring tube on the inlet end to form a first coupling zone and affixed to the measuring tube on the outlet end to form a second coupling zone; and a transducer housing affixed to the inlet tube piece and the outlet tube piece. An exciter mechanism, for driving at least the measuring tube, and a sensor arrangement, for registering oscillations at least of the measuring tube, are, in each case, secured, at least in part, to the counteroscillator. Additionally, on the inlet side, an cantilever is so coupled in the region of the coupling zone with the inlet tube piece and the measuring tube, that the center of mass of the cantilever lies in the region of the inlet tube piece, and, on the outlet side, an cantilever is so coupled in the region of the coupling zone with the outlet tube piece and the measuring tube, that the center of mass of the cantilever lies in the region of the outlet tube piece. Furthermore, the measuring transducer includes connection lines, especially connection lines for the exciter mechanism and/or for the sensor arrangement, with at least one of the connection lines being secured to at least one of the two cantilevers.
    • 测量传感器包括:测量管,至少有时在操作期间和在用于输送介质时起振动作用,其中所述测量管通过入口端处的入口管件和出口端的出口管件与管道连通 ; 固定在入口端的测量管上以形成第一联接区并在出口端固定到测量管以形成第二联接区的反倾析器; 以及附接到入口管件和出口管件的换能器壳体。 用于至少驱动测量管的激励器机构和用于记录至少测量管的振荡的传感器装置在每种情况下至少部分地被固定到反相振荡器。 此外,在入口侧,悬臂在耦合区域的区域与入口管件和测量管联接,悬臂的质心位于入口管件的区域中,并且在 出口侧,悬臂在与出口管件和测量管的联接区域的区域中联接,悬臂的质心位于出口管件的区域中。 此外,测量换能器包括连接线,尤其是用于激励器机构和/或用于传感器装置的连接线,其中至少一个连接线固定到两个悬臂中的至少一个。