FR2860592A1 - Current measurement device for e.g. truck, has calculating unit with correctors to correct errors of measurements of Hall Effect and magneto-resistive sensors respectively using measurements from magneto-resistive and Hall Effect sensors - Google Patents

Abstract

The device (1) has Hall Effect sensors (101, 102) and magneto-resistive sensors (201, 202) that are placed close to each other and on both sides of a conductor (40) carrying current to be measured. A calculating unit (30) has correctors to correct errors of measurements of the sensors (101, 102, 201, 202) respectively using the measurements from the sensors (201, 202, 101, 102) based on amplitude of the current.

Description

Non-contact, high dynamic, robust current measuring device

  The present invention relates to the realization of a current measuring device by magnetic effect, implementing an assembly of inexpensive sensors so that the defects of one are corrected by the others.

  It is known, in the prior art, current measuring devices based on two general principles: 1. Current measurement by shunt where a low value resistor is inserted into the circuit to be measured. The voltage measurement at its terminals makes it easy to calculate the current in the circuit. The disadvantages are: - The complexity of the installation: it is necessary to open the circuit to be measured and to insert an element in a zone of power. It is sometimes necessary to insert shunts of different values according to the expected current.

  Poor performance due to necessary voltage drop, especially at high currents 2. Magnetic current measurement with Hall effect measurement, magnetoresistive, with or without ferrite, open loop (direct measurement) or closed loop (zero measurement and application of a compensation field). The disadvantages are: - Low measurement dynamics High cost when precision is required Overload sensitivity For many applications these devices are sufficient, but there are areas whose requirements are poorly met; these are particularly those for which performance and measurement dynamics are paramount, especially for mobile installations where operating conditions are particularly severe.

  The present invention aims to overcome some disadvantages of the prior art by providing a simple measuring device, without contact, easy to manufacture and integrate in complex equipment, consisting of an assembly of ordinary quality sensors.

  This object is achieved by a measurement device based on the magnetic effect, but simultaneously using two types of sensors arranged in the vicinity of the same electrical conductor carrying the current to be measured: a set of Hall effect sensors, particularly suitable for the measurement of strong fields, therefore reserved for large current measurements, a set of magnetoresistive effect sensors, particularly suited to the measurement of weak fields.

  According to another particularity, each type of sensor is arranged in pairs, on either side of the conductor, in a so-called differential arrangement where the axes of sensitivity are parallel and opposite. This arrangement makes it possible to compensate for external disturbing magnetic fields such as the terrestrial magnetic field. According to another feature, the measuring device comprises a calculation and control element which makes it possible, by analyzing the measurements made by the first type of sensor. , to correct the defects of the second type of sensors and vice versa. A non-limiting example is that where the zero drift Hall effect sensors is corrected by the measurements from magneto-resistive sensors when the amplitude of the current to be measured allows it. Conversely, the hysteresis errors of the magnetoresistive sensors, errors which appear when they have been subjected to very strong fields, can be corrected thanks to the knowledge of the amplitude of this disturbing field measured by the effect sensors. Lobby.

  Other features and advantages of the present invention will appear more clearly on reading the following description, made with reference to the accompanying drawings, in which: - Figure 1 shows a layout diagram of the hall sensors and magnetoresistive constituting the current measuring device, according to an embodiment of the present invention; FIG. 2 shows a block diagram representative of the device and the treatments carried out, according to an embodiment of the present invention; Figure 1 shows a diagram of the elements constituting the current measuring device (1), according to an embodiment of the present invention. Figure la shows the arrangement of the sensors in top view, vertical measurement conductor (40), in section, Figure 1b shows the arrangement of the sensors, horizontal measuring conductor. The current measuring device (1) comprises a Hall effect measuring chain (10) consisting of a pair of Hall effect magnetic field sensors (101), (102) connected to a differential amplifier (103), which transmits its measurements to the computing device (30). These two sensors (101) and (102) are arranged on either side of the conductor (40) carrying the current to be measured. The current measuring device (1) further comprises a magneto-resistive effect measuring chain (20) consisting of a pair of magneto-resistive magnetic field sensors (201), (202) connected to an amplifier differential (203), which also transmits its measurements to the computing device (30). These two sensors (201) and (202) are arranged on either side of the conductor (40) carrying the current to be measured and in the vicinity of Hall effect sensors (101) and (102) so that they are subject to the same magnetic field. The calculating member (30) continuously and simultaneously analyzes the measurements from the two chains (10) and (20) according to a process described hereinafter and symbolized in FIG. 2.

  Figure 2 shows symbolically the processing that is performed by the computing device (30). The pair of Hall sensors (101) and (102) is conditioned by the differential amplifier (103) whose output is used by: an error correcting amplifier (311), which transmits the corrected measurements to a switch (34). ) the error corrector (321) of the magnetoresistive processing chain, a threshold detector (33) which controls the switch (34). This threshold detector is dimensioned so that it positions the switch (34) on the output of the error corrector (321) of the magneto-resistive effect measurement chain when the current measured by the hall effect measurement chain is below a threshold ls and on the output of the error corrector (311) of the hall effect measurement chain when the current measured by the hall effect measurement chain (10) is greater than this threshold Is.

  The pair of magneto-resistive sensors (201) and (202) is conditioned by the differential amplifier (203) whose output is used by: an error correcting amplifier (321), which transmits the corrected measurements to the switch ( 34) - the error corrector (311) of the Hall processing chain It will be noted that the control of the switch (34) is based on the hall effect measurements not corrected by the corrector (311). Indeed the accuracy required to control the switch (34) is low enough not to require correction in most cases of use. A variant of the presented solution is to use the output of the corrector (311) to control the threshold detector (33), but in this case precautions must be taken to avoid any risk of instability.

  Another variant of the device consists in replacing the switch (34) with any type of filter capable of performing a weighted average of the outputs of the hall effect measuring chain (10) and of the magneto-resistive effect measuring chain ( 20) as a function of current measurements by hall effect.

  The outputs of the error correctors (311) of the hall-effect measurement chain and (321) of the magneto-resistive-effect measuring chain are connected to the switch (34) controlled by the output of the threshold detector (33) .

  The output of the switch (34) directly gives the value of the measured current.

  With reference to Figure 2, the operation of the device is as follows. The computing device having a memory, correction coefficients correctors (311) and (321) are available from power on, but they will be updated automatically and permanently according to the process described herein. -after.

  If the current to be measured is small, the output of the amplifier (103) is below the threshold of the threshold detector (33). The switch (34) therefore connects the output of the corrector (321) to the output of the device. It is the magneto-resistive measurement chain that is used. The Hall effect measurement system operates in parallel, but its measurements are continuously compared with magneto-resistive measurements. The differences are used by the computing unit to determine new coefficients for the corrector (311) of the hall effect measurement chain.

  If the current to be measured becomes large, the output of the amplifier (103) exceeds the threshold of the threshold detector (33). The switch (34) therefore connects the output of the corrector (311) to the output of the device. It is the hall effect measuring chain that is used. These measurements are furthermore used by the calculation unit to determine new coefficients for the corrector (321) of the magneto-resistive effect measurement chain, in particular to predict the zero offset of the magneto-resistive sensors when these or their immediate magnetic neighborhood has been subjected to very strong magnetic fields, cases of measurement of strong currents. This case is not limiting because all the error parameters of the magneto-resistive sensors can be identified, such as the hysteresis effects, by an appropriate filter.

  The abrupt switchover of the switch (34) may reveal device transfer function discontinuities, so a variant of the device uses instead of the switch (34) a weighted average filter of the magneto-resistive and hall measurements. The weighting coefficients are determined according to the uncorrected hall measurements from the hall measurement chain (10).

  This arrangement or any other equivalent arrangement makes it possible to constitute a very inexpensive current measuring device. It only requires small, widely used components of medium precision. All components can be arranged flat on an electronic card according to the usual techniques of manufacturing printed circuits. No special assembly or precision machining is required.

  The proposed current measurement system is intended more particularly for mobile installations where cost, consumption, reliability and robustness are paramount criteria.

  The device according to the invention is particularly intended for the electrical management of trucks, boats, automobiles, whether electricity is used as an auxiliary source or as a main means of propulsion.

  The device according to the invention makes it possible in particular to estimate the state of charge of batteries by current integration and to obtain a high measurement fidelity without requiring fastidious and uncertain parameterizations.

  It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration, but may be modified within the scope defined by the scope of the appended claims, and the invention should not be limited to the details given above.

Claims (7)

  Non-contact current measurement device comprising different magnetic sensors associated with a calculation means. The current measuring device (1) is characterized in that it comprises: a set of Hall effect magnetic field sensors (101), (102) arranged in a differential measurement configuration, on either side of the conductor carrying the current to be measured (40); a set of magneto-resistive magnetic field sensors (201), (202) disposed in a differential measurement configuration, near the hall effect sensors (101), (102) and on either side of the driver carrying the current to be measured (40); computing means (30) receiving the information from the magnetoresistive sensors and hall, capable of making corrections to these measurements; Current measuring device (1) according to claim 1, characterized in that the calculating means (30) of the current measuring device (1) comprises a corrector (311) which uses the measurements made by the sensors. magnetoresistive means (201), (202) for correcting the measurement errors of the hall effect sensors (101), (102) when the measured current is below the normal operating limit of the magnetoresistive sensors (201), ( 202); Current measuring device (1), according to claim 1, characterized in that the calculating means (30) of the current measuring device (1) comprises a corrector (321) which uses the measurements made by the sensors Hall effect (101), (102) for correcting measurement errors of magneto-resistive sensors (201), (202) when the measured current is greater than the normal operating limit of the magnetoresistive sensors (201), ( 202); Current measuring device (1) according to claim 1, characterized in that the calculating means (30) of the current measuring device (1) comprises a level detector (33) which determines whether the amplitude of the magnetic field measured by the hall effect sensors is CLAIMS,   less than or greater than the normal operating limit of magneto-resistive sensors; Current measuring device (1) according to claims 1 to 4, characterized in that the calculating means (30) of the current measuring device (1) comprises a switch (34) which selects the measuring means magneto-resistive when the amplitude of the magnetic field measured by the Hall sensors is less than the normal operating limit of the magneto-resistive sensors; Current measuring device (1) according to claims 1 to 4, characterized in that the calculating means (30) of the current measuring device (1) comprises a switch (34) which selects the measuring means Hall effect when the magnitude of the magnetic field measured by the Hall effect sensors exceeds the normal operating limit of magneto-resistive sensors; Current measuring device (1), according to claims 1 to 6, characterized in that the switch (34) of the calculating means (30) of the current measuring device (1) can be replaced by a filter effecting a weighted average of the measurements from both the hall effect measurement chain and the magneto-resistive effect measurement chain, the weighting coefficients depending on the magnetic field level measured by the hall effect measurement chain.