WO2014019405A1 - 在壳体内多磁块不均匀分布磁通量的传感器 - Google Patents
在壳体内多磁块不均匀分布磁通量的传感器 Download PDFInfo
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- WO2014019405A1 WO2014019405A1 PCT/CN2013/076773 CN2013076773W WO2014019405A1 WO 2014019405 A1 WO2014019405 A1 WO 2014019405A1 CN 2013076773 W CN2013076773 W CN 2013076773W WO 2014019405 A1 WO2014019405 A1 WO 2014019405A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/12—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means
- G01D5/14—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage
- G01D5/142—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage using Hall-effect devices
- G01D5/145—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage using Hall-effect devices influenced by the relative movement between the Hall device and magnetic fields
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/12—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means
- G01D5/244—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing characteristics of pulses or pulse trains; generating pulses or pulse trains
- G01D5/245—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing characteristics of pulses or pulse trains; generating pulses or pulse trains using a variable number of pulses in a train
- G01D5/2451—Incremental encoders
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/12—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means
- G01D5/14—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage
- G01D5/20—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01L—MEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
- G01L3/00—Measuring torque, work, mechanical power, or mechanical efficiency, in general
- G01L3/02—Rotary-transmission dynamometers
- G01L3/04—Rotary-transmission dynamometers wherein the torque-transmitting element comprises a torsionally-flexible shaft
- G01L3/10—Rotary-transmission dynamometers wherein the torque-transmitting element comprises a torsionally-flexible shaft involving electric or magnetic means for indicating
- G01L3/101—Rotary-transmission dynamometers wherein the torque-transmitting element comprises a torsionally-flexible shaft involving electric or magnetic means for indicating involving magnetic or electromagnetic means
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01P—MEASURING LINEAR OR ANGULAR SPEED, ACCELERATION, DECELERATION, OR SHOCK; INDICATING PRESENCE, ABSENCE, OR DIRECTION, OF MOVEMENT
- G01P3/00—Measuring linear or angular speed; Measuring differences of linear or angular speeds
- G01P3/42—Devices characterised by the use of electric or magnetic means
- G01P3/44—Devices characterised by the use of electric or magnetic means for measuring angular speed
- G01P3/48—Devices characterised by the use of electric or magnetic means for measuring angular speed by measuring frequency of generated current or voltage
- G01P3/481—Devices characterised by the use of electric or magnetic means for measuring angular speed by measuring frequency of generated current or voltage of pulse signals
- G01P3/487—Devices characterised by the use of electric or magnetic means for measuring angular speed by measuring frequency of generated current or voltage of pulse signals delivered by rotating magnets
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03M—CODING; DECODING; CODE CONVERSION IN GENERAL
- H03M1/00—Analogue/digital conversion; Digital/analogue conversion
- H03M1/66—Digital/analogue converters
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D2205/00—Indexing scheme relating to details of means for transferring or converting the output of a sensing member
- G01D2205/80—Manufacturing details of magnetic targets for magnetic encoders
Definitions
- the present invention belongs to the technical field of magnetic induction providing signals, and more particularly to a technique for performing multi-point magnetic induction to provide a control signal on a rotating member.
- the Chinese patent 201020295192.0 "Hook-type torque sensing device" applied by Yebao Vehicle Industry (Kunshan) Co., Ltd. discloses a sensing device for assisting bicycles.
- the sensing device includes a magnetic member and an elastic member to cooperate, and the torque is transmitted.
- Sensing device After a long period of use, the change in the elastic modulus of the elastic member causes a change in the control effect of the sensing signal and the controlled motor, and the assisting effect becomes incompatible with the human assisting need.
- the design of the elastic member is complicated and the manufacturing cost is high.
- the Chinese patent 01201843.0 Automatic assisted bicycle automatic detecting device
- the magnetic disk has a spring on the inner disc, and the inner and outer discs are spring-reset.
- the electric signals generated by the two Halls on the inner and outer discs are used to indicate the force, speed and steering. .
- Elastic parts are not durable: After a long period of use, the change of the elastic modulus of the elastic parts will cause the control signal and the control effect of the controlled motor to change, and the boosting effect becomes incompatible with the human assistance needs. Complex and costly.
- Each disk group is the same and the magnetic poles are set in the same way, but can not indicate the respective positions of different disk groups, and can not express the special power requirements of different positions: from Figures 3, 4, 5, 6 and the specification of 01201843.0 patent
- the description in the second paragraph of page 2 shows that the magnetic poles of each magnetic disk group (including one magnetic disk 4, one magnetic disk 5, and one magnetic disk 6) are arranged in the same way, that is, they are simply from different positions of the inner wheel.
- the same set of magnetic disk sets are set up, which cannot indicate the respective positions of different magnetic disk groups, and cannot indicate the motion state of a specific position.
- the pedals and the positions corresponding to the pedals are in motion and have their own. Special power requirements, but the same structure of the various magnetic disk groups of the patent cannot express the special power demand at different positions on the pedal.
- the technical solution of the patent of 01201843.0 is used to assist the bicycle, the number of the magnetic disk group is limited to 8 or less, the control signal is too small, and the man-machine cooperation is not ideal.
- the signal pattern of the Hall output is close to a horizontal line. The signal has no control function and cannot control the motor, so that when the power is particularly needed, the power-saving function is lost.
- the blind area of the signal reaches a 45-degree angle.
- the pedal foot pedal is the smallest at the apex, and the angle of 10-45 degrees from the apex is the most needed area.
- the angle between the various magnetic disk groups of the patent is 45 degrees, and there is no magnetic disk group in the 10-45 degree angle region from the apex of the pedal, and there is no control signal, and the result is that when the power is most needed
- the motor that assists the bicycle does not help.
- the diameter of the turntable is less than 20 cm, and the number of the magnetic disk group is limited to 8 groups, and the number of the magnetic disk group cannot be increased arbitrarily.
- the human-machine coordination is not ideal, and the power is not activated at the start.
- the boosting demand does not match the power supply.
- the rider's comfort is poor. If the number of the magnetic disk group is forcibly increased, the sensing signal loses the power control function.
- Permanent magnet magnet is used to indicate the fixed position of the pedal, and three Halls indicate the position of the pedal: Since the pedal and the moving disc are synchronously rotated, one position is fixed at two positions on the moving disc corresponding to the two pedals. Permanent magnet steel, where is the position of a certain pedal, then the corresponding permanent magnet magnet is also turned to the position; but only when there is a position in the Hall, the control signal can be sent through the Hall to command the motor of the bicycle. The power needed to turn.
- Disadvantages (2) Cannot use only one Hall, and the three Halls must cause the original control error of the three control signals, so that the power demand model is distorted, and naturally the power output is inconsistent with the power demand: the assist bicycle is either one or two.
- the sensing signal of the control motor can only be input to the motor controller with one sensing signal to achieve the purpose of controlling the motor; and the patent uses three Hall control motors, it is necessary to control three of the three Halls.
- the signals are combined into one combined control signal before they can be input to the motor controller.
- the sensing parameters of the three Halls cannot be the same, especially since the sensing parameters of the three Halls may vary greatly due to changes in ambient temperature and long usage time. The result is the same boosting demand when different Halls are used.
- the output is different voltages, which causes the motor to produce different boosting outputs.
- the boosting output is inconsistent with the boosting demand.
- the output of different Halls may be the same voltage, which causes the motor to produce the same boosting output. A problem arises in which the boost output is inconsistent with the boost demand.
- the combined control signal is easy to generate signal drift, so that the combined control signal does not match the motor controller, and the demand model is distorted: the sensing parameters of the three Halls may vary greatly due to changes in ambient temperature and long use time.
- the three control signal connection points of the three Halls must change, and the combined control signal generated by the same power demand will produce a segmented signal drift, and the combined control signal will generate signal distortion as a whole, that is, the power demand model distortion If the motor controller selects any one of the three control signals as the reference, the problem that the boosting output and the boosting demand are inconsistent will be generated.
- the sensing site can not be increased arbitrarily, the sensing site is too small, the motor is not stable, making the rider feel very uncomfortable: because of the disadvantages (1) and disadvantages (2) are the most If the number of erres is greater than one, it is obvious that the number of Halls is more and more, and the disadvantages (1) and (2) are more serious. Therefore, the power-assisted bicycle provided by this patent can only be a power-assisted bicycle that makes the rider feel very uncomfortable.
- the blind area of the signal reaches a 42-degree angle.
- the start-up requires assistance, it does not get the boost: It is well known that people step on the bicycle pedal with the minimum moment at the apex, and the angle from the apex of 10-45 degrees is the area most in need of assistance. However, the angle between the Halls of the patent is 42.5-43.5 degrees. There is no Hall in the 10-42 degree angle range from the apex of the pedal, and there is no control signal. The result is the most need for assistance. However, the motor that assists the bicycle does not help.
- this patent is a technical solution for controlling the assist mode with multiple Halls, because only a plurality of Halls can be used to indicate the rotational position of the pedal, and multiple control signals of multiple Halls must have original errors, and the combined control signals are combined. It is easy to generate signal drift, which can cause the distortion of the power demand model, that is, the same power demand at different times, but obtain different power-assising effects; the more the number of Halls, the more serious the distortion of the power-assisted demand model, which limits the number of Halls. When the number of Halls is small and the motor is running, it is not stable, making the rider feel uncomfortable and unable to get help at startup. It is necessary to make the demand model not distorted, and to keep the motor running smoothly.
- the number of permanent magnet blocks can be increased as much as possible, and the displacement information of the ring groove can be rotated to the maximum extent, and the output information can be accurately positioned.
- the Hall and the plurality of permanent magnet blocks are fixed at a relative position by a combination member. sensor. It can be used on a power-assisted bicycle without the use of elastic members and other mechanical measuring torques. It can also match the power-assising demand with the provided power, and the motor runs smoothly to assist the bicycle sensor.
- the idea of the present invention is that in a Hall sensible range, an annular groove rotates on the disk with a plurality of permanent magnet blocks to alternate the north and south magnetic polarities on the side of the Hall, so that one Hall can feel The motion signal of all permanent magnet blocks.
- the variation of multiple permanent magnet blocks is mainly the change of magnetic polarity and the change of magnetic flux.
- the purpose is to enable Hall to obtain the motion signal of permanent magnet block with specific position, more precise position, stronger control function and more quantity.
- the magnetic polarity of multiple permanent magnet blocks alternates with the south pole north pole, so that the signal generated by Hall is a rectangular wave, which makes the signal control function stronger and more numerous.
- the magnetic flux changes of multiple permanent magnet blocks can make the signal generated by Hall express.
- the position of the permanent magnet block is more precise so that the motion state of the annular groove rotating disk at a specific position can be expressed.
- the relative position of the sensing element Hall and the plurality of permanent magnet blocks is fixed by a mechanical structural assembly to make the sensing signal stable and reliable.
- the rectangular wave signal outputted by the Hall is converted into a digital signal, so that the digital signal of the Hall is digitized, and a mathematical model for assisting the best function of the human body can be added in the process of digitizing, and the mathematical model can be assisted by human beings.
- the machine cooperates to make random adjustments.
- Overcoming the sinusoidal signal output of the prior art Hall is difficult to digitize, only the analog signal processing can be performed, and the self-adaptive power-assisted model can not be added, and the power-assisted model which can only extract the condition limited by the speed signal can be overcome and overcome.
- the problem that the human machine cannot be optimally matched.
- the structure of the invention is:
- a sensor for distributing magnetic flux in a plurality of magnetic blocks in a casing comprising a sensor element sequentially connected, a power assist model processor 21, a digital-to-analog converter 27, and an operational amplifier 28;
- the sensing element is an element that converts the rotational motion of the annular groove rotating disk 1 into a rectangular wave signal output;
- the sensing element includes an annular groove rotating disk 1, an annular groove fixing disk 40, a Hall 3, and a plurality of permanent magnet blocks 2, the concave groove rotating disk 1 and the annular groove fixing disk 40 are opposite to each other, and the annular groove fixing disk 40 is fitted in the annular groove of the annular groove rotating disk 1, into two a concave inner casing with a relatively rotatable disk, a concave surface of the two disks is sandwiched by a hollow ring 41; and a plurality of permanent magnet blocks 2 are fixedly disposed on the annular groove rotating disk 1 at the position of the hollow ring 41, the plurality of The permanent magnet blocks 2 are distributed
- a Hall 3 is fixedly disposed on the annular groove fixing plate 40 of the hollow ring 41, and the Hall 3 is disposed close to the permanent magnet block.
- Hall 3 is a Hall that generates a rectangular wave output signal to the opposite magnetic polarity
- the assist model processor 21 is a signal form converter that converts the digital signal rotated by the annular groove rotating disk 1 into a power model digital signal;
- the assist model processor 21 includes an analog to digital conversion and peak recognizer 22, a boost start point selector 23, a magnetic block tachometer 24, a boost model memory 25, and a boost model calculator 26;
- the analog-to-digital conversion and peak identifier 22 is connected to the sensing element, and the analog-to-digital conversion and peak identifier 22 recognizes the rectangular wave signal input from the Hall 3 in the sensing element to identify the peak of each rectangular wave, and changes each rectangular wave signal into Different digital signals are labeled for each rectangular wave, and the analog-to-digital conversion and peak identifier 22 outputs a magnetic block motion digital signal marked with a magnetic block position order;
- the analog-to-digital conversion and peak recognizer 22 is connected to the assist start point selector 23 and the magnetic block rotational speed calculator 24, respectively, and the boost start point selector 23 is connected to the magnetic block rotational speed calculator 24; the magnetic block rotational speed calculator 24 uses analog-to-digital conversion and peaks.
- the digital signal of the magnetic block movement marked with the position of the magnetic block is input by the identifier 22, and the rotational speed of the circular groove rotating disk 1 is calculated, and the digital signal of the rotational speed of the circular groove rotating disk 1 is transmitted to the assisting start point selector 23 to assist the starting point.
- the selector 23 determines a rectangular wave corresponding to the assist starting point under a certain rotational speed condition by using the magnetic block motion digital signal marked with the magnetic block position order and the rotational speed digital signal of the annular groove rotating disk 1 Determining the starting point magnetic block;
- the assist starting point selector 23 and the magnetic block rotational speed calculator 24 are respectively connected to the assist model calculator 26, and the assist model memory 25 is also connected to the assist model calculator 26; the assist model calculator 26 uses the assist starting point of the assist starting point selector 23 The block, and the rotational condition of the disk 1 by the annular groove of the magnetic block rotational speed calculator 24, selects one of the assist model functions in the assist model memory 25, and rotates the starting magnetic block and the annular groove to rotate the disk 1 These two conditions are substituted into the assist model function to calculate the digital signal of the assist model suitable for these two conditions, namely the assist model calculator. 26 output power model digital signal;
- the digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model
- the boost model calculator 26 is connected to the digital-to-analog converter 27, and the digital-to-analog converter 27 converts the assist model digital signal of the assist model calculator 26 into the assist model analog signal;
- the operational amplifier 28 is a boost model analog signal that converts the assist model analog signal of the digital-to-analog converter 27 into a rated voltage range.
- the annular groove rotating disk 1 is fitted with the annular groove fixing plate 40, and is relatively rotatable, thereby ensuring that the rotating position of the rotating disk 1 in the annular groove is not changed, and the sensing positions of the Hall 3 and all the permanent magnetic blocks 2 are not changed, so that
- the output signal of the Hall 3 is only related to the rotation of all the permanent magnet blocks 2, and is independent of the objects of the annular groove rotating disk 1 and the annular groove fixing disk 40; if the annular groove rotates the disk 1 and the annular groove fixing disk 40 is made of a metal material, and may have a shielding effect. Therefore, the ring 3 and the annular groove fixing plate 40 are used to rotate the Hall 3 and all the permanent magnet blocks 2 in the hollow ring 41 for sensing, thereby improving the Hall 3 The reliability and authenticity of the signal.
- the annular groove fixing plate 40 When the annular groove fixing plate 40 is fixed to an object, the annular groove is rotated to rotate the disk 1, and the respective permanent magnets 2 on the annular groove rotating disk 1 are swept over the Hall 3 on the annular groove fixing plate 40.
- Each permanent magnet block 2 can cause the Hall 3 to generate an electrical signal. Since the magnetic polarities of the adjacent permanent magnet blocks 2 are opposite, that is, the magnetic polarities of all the permanent magnet blocks 2 face the Hall 3 alternately south and north, the Hall 3 generates an electric signal as a rectangular wave signal, and the rectangular wave signal is convenient for digitization. Processing signals for digital control.
- the Hall 3 can only generate a sine wave signal, so it can only be used for analog control; once the Hall 3 changes in the sensing parameters, the simulation Control can be distorted.
- the present invention realizes digital control by using a rectangular wave signal without causing a problem of controlling distortion.
- the annular groove rotating plate 1 may be a plastic plate, a high-strength plate, a copper plate, an aluminum plate or the like which is not easily deformed.
- the annular groove rotates the disk 1 to rotate, and the center of the rotation is the center of the circle in which the plurality of permanent magnet blocks 2 are distributed in a circular shape.
- the purpose of the plurality of permanent magnet blocks 2 being circularly distributed is that the movement state of all the permanent magnet blocks 2 on the rotating disk can be felt by only one Hall 3, that is, the permanent magnetic block 2 on the rotating disk of the annular groove is felt.
- This Hall 3 can express the motion state of the permanent magnet block 2 with a continuous electrical signal, and because all the permanent magnet blocks 2 are respectively fixed at
- the annular groove rotating disk, that is, the annular groove rotating the disk 1 the continuous electrical signal generated by the Hall 3 can express the motion state of the annular groove rotating disk. If this continuous electrical signal is used to control other objects, this continuous electrical signal is the control signal.
- the sensing signal processor If it is used to control the motor of the bicycle, it is also necessary to use a single-chip computer or other electronic components as the sensing signal processor to convert the position, velocity and acceleration in the control signal into a boosting signal that needs much assistance.
- the function of the conversion is the power.
- the meaning of the magnetic fluxes of the plurality of permanent magnet blocks 2 is different: the pulse signals generated by the Hall 3 are not exactly the same, but the pulse signals with different peak-to-valley differences are distinguished by different pulse signals. Different positions of the magnet block 2, so that the motion state of the permanent magnet block 2 at different positions can be obtained. It is possible to accurately express a certain position of the rotating disk of the annular groove, or each of the motion states of the permanent magnet block 2. If used to assist bicycles, it can accurately express the need for power in different positions of the pedals, so that the expression of the assistance demand is more accurate, and the cooperation between the vehicle and the person is more consistent.
- the magnetic fluxes of the plurality of permanent magnet blocks 2 are different, that is, the magnetic fluxes of the plurality of permanent magnet blocks 2 are varied, and the range of the change should be the range of magnetic flux that can be sensed by the same Hall 3 with the same position, that is, more The highest and lowest values of the magnetic flux of the permanent magnet block 2 should be within the range of the magnetic flux that Hall 3 can sense.
- the Hall 3 is located close to the permanent magnet block 2 and can sense the magnetic flux of the permanent magnet block 2, and aims to sense the motion state of the permanent magnet block 2, that is, the moving position, speed, and acceleration, by using the Hall 3.
- the opposite magnetic polarity of the adjacent permanent magnet block 2 is an important technical feature.
- the magnetic polarity distribution pattern of all the permanent magnet blocks 2 is N pole, S pole, N pole, S pole, N pole, S pole... 3 output high and low phase rectangular wave signal, as a ring-shaped rotating disk with limited size, it is necessary to obtain as many accurate change signals as possible in one rotation.
- rectangular wave should be used. Since the peak-to-valley value of the rectangular wave signal changes for a short period of time, as many control signals as possible can be generated in a certain period of time.
- the structures of the adjacent permanent magnet blocks 2 having opposite magnetic polarities generate rectangular waves, and the structures of the adjacent permanent magnet blocks 2 having the same magnetic polarity generate sinusoidal waves, particularly when used to assist bicycles, the annular groove as a sensing member rotates.
- the disc is generally limited to a diameter of 10-15 cm. In this limited range, a signal with a control function is obtained, and one rotation is made, and the rectangular wave is generated 7 to 9 times more than the number of pulses that the sine wave can provide.
- the structure with the opposite magnetic polarity of the adjacent permanent magnet block 2 has a better control effect on the assist bicycle, and the person and the car cooperate better, and the rider feels more comfortable.
- the assist model processor 21 is a signal form converter that converts the digital signal rotated by the annular groove rotating disk 1 into a power model digital signal;
- the assist model processor 21 includes an analog-to-digital conversion and peak recognizer 22, a boost start point selector 23, a magnetic block rotational speed calculator 24, a boost model memory 25, and a boost model calculator 26; the processing ideas of these components for the signal are:
- the rectangular wave signal of the Hall 3 in the sensing element is decomposed into a position digital signal indicating the position of the magnetic block 2, and a speed digital signal indicating the rotational speed of the circular groove rotating disk 1.
- the position and speed are digital signals, the position and The speed is processed by the assisted mathematical model, and the mathematical model can be designed according to the best feeling of the human being, so that the assisting model digital signal output by the model processor 21 has the best assisting mathematical model, and the starting point of the assisting mathematical model And the termination point, because there is a digital signal of the position of the magnetic block 2, the starting point and the ending point are accurate enough to be completely synchronized with the human power demand.
- the problem that the prior art does not have the position signal of the magnetic block 2 causes the human power demand and the power assist model to be mismatched, and the operation of the power assist model is delayed by the power demand, and the problem of the prior art is solved, and the power is only forced to be small. Force, we must give strength to the small force, do not force and give power and other problems.
- the connection relationship between the components in the model processor 21 and The function is as follows:
- the analog-to-digital conversion and peak identifier 22 is connected to the sensing element, and the analog-to-digital conversion and peak identifier 22 recognizes the rectangular wave signal input from the Hall 3 in the sensing element to identify the peak of each rectangular wave, and changes each rectangular wave signal into Different digital signals are labeled for each rectangular wave, and the analog-to-digital conversion and peak recognizer 22 outputs a rectangular wave signal labeled with the order of the magnetic block. In this way, the rectangular wave signal having the peak difference of the waveform is changed into a rectangular wave signal marked with data, and it is convenient to convert the rectangular wave peak into rectangular wave position data in the subsequent digitization process for arithmetic processing.
- the analog-to-digital conversion and peak recognizer 22 is a processor that converts the peak of the rectangular wave to the position of the magnetic block and becomes a digital signal that marks the position of the magnetic block with data. This is an important invention that distinguishes the present invention from the existing assisted bicycle. With the digital signal indicating the position of the magnetic block with data, the present invention can find one or each magnetic on the circular groove rotating disk 1 which circulates in a circular motion.
- the motor 30 does not rotate when there is a need for assistance, and the motor 30 does not stop when the power is not required, and even causes a collision accident.
- the analog-to-digital conversion and peak recognizer 22 is connected to the assist start point selector 23 and the magnetic block rotational speed calculator 24, respectively, and the boost start point selector 23 is connected to the magnetic block rotational speed calculator 24; the magnetic block rotational speed calculator 24 uses analog-to-digital conversion and peaks.
- the digital signal of the magnetic block movement marked with the position of the magnetic block is input by the identifier 22, and the rotational speed of the circular groove rotating disk 1 is calculated, and the digital signal of the rotational speed of the circular groove rotating disk 1 is transmitted to the assisting start point selector 23 to assist the starting point.
- the selector 23 determines a rectangular wave corresponding to the assist starting point under a certain rotational speed condition by using the magnetic block motion digital signal marked with the magnetic block position order and the rotational speed digital signal of the annular groove rotating disk 1 Determine the starting point magnet block. Since the determined starting point magnetic block is a rectangular wave with data annotation, the assist starting point magnetic block has a unique corresponding position of the magnetic block 2, so that the assisting start point selector 23 completes the position of the magnetic block 2 for finding the assist starting point. It is also possible to determine when a certain magnetic block 2 is in position, to start or end the motor for some kind of assisted model motion. This achieves the synchronous movement of the specific magnetic block 2 of the human control ring groove rotating disk 1.
- the specific magnetic block 2 controls the motor 30 to perform a specific synchronous rotation, thereby realizing the purpose of synchronously controlling the motor, and the starting point and the end point of the control are not inaccurate. There is no problem with the control of the start and end delays. However, when the existing assist bicycle is unable to find the starting position synchronized with the person when starting and assisting, the problem of the starting point and the end point delay of the control will be generated.
- the assist starting point selector 23 and the magnetic block rotational speed calculator 24 are respectively connected to the assist model calculator 26, and the assist model memory 25 is also connected to the assist model calculator 26; the assist model calculator 26 uses the assist starting point of the assist starting point selector 23 The block, and the rotational condition of the disk 1 by the annular groove of the magnetic block rotational speed calculator 24, selects one of the assist model functions in the assist model memory 25, and rotates the starting magnetic block and the annular groove to rotate the disk 1 These two conditions are substituted into the assist model function to calculate the digital signal of the assist model suitable for these two conditions, namely the assist model calculator. 26 can output the boost model digital signal.
- the digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model.
- the assist model calculator 26 is connected to the digital-to-analog converter 27, which converts the assist model digital signal of the assist model calculator 26 into a boost model analog signal. In order to output an analog signal of the boost model to the motor controller 29 which can only process the analog signal.
- the operational amplifier 28 is an assist model analog signal that converts the assist model analog signal of the digital-to-analog converter 27 into a rated voltage range.
- the digital-to-analog converter 27 is connected to the operational amplifier 28.
- the power-assisted model analog signal of the digital-to-analog converter 27 solves the power-assisted model problem, but the voltage of the power-assisted model signal cannot meet the needs of the motor controller 29, so an operational amplifier is also used.
- the 28 assisted model analog signal required to convert the boost model analog signal into the rated voltage range can be transmitted to the motor controller 29.
- the signals output by the signal processing components in the sensor of the present invention are:
- Hall 3 outputs a rectangular wave signal
- the assist model processor 21 outputs the assist model digital signal
- the analog to digital conversion and peak recognizer 22 outputs a digital signal of the magnetic block motion marked with the order of the magnetic block position
- the assist starting point selector 23 outputs a determined start position signal of the assist starting point magnet block
- the magnetic block rotational speed calculator 24 calculates and outputs a digital signal of the rotational speed of the annular groove rotating disk 1;
- the assist model memory 25 stores a plurality of boost model function spares, and outputs a digital signal of the selected boost model function;
- the boost model calculator 26 calculates and outputs a boost model digital signal to be used for the control function;
- the digital-to-analog converter 27 outputs an assist model analog signal that converts the power model digital signal into a power model
- the operational amplifier 28 outputs an assist model analog signal that converts the assist model analog signal into a rated voltage range
- the thermistor R6 ensures that the operational amplifier 28 outputs a boost model analog signal of the rated voltage range, that is, the standard boost model analog signal.
- a thermistor R6 is provided to solve the problem of the analog model analog signal drift, and the thermistor R6 is connected between the input terminal and the output terminal of the operational amplifier 28.
- the boost model processor 21 is a single chip microcomputer 31 to which a clock circuit 32 is connected.
- the functions of the analog-to-digital conversion and peak recognizer 22, the assist start point selector 23, the magnetic block rotational speed calculator 24, the assist model memory 25, and the assist model calculator 26 are completed by the single chip microcomputer 31.
- the clock signal of the clock circuit 32 is for distinguishing the rectangular wave signals input from the Hall 3, and it is preferable that the length of each clock signal is 0.001 second.
- the mechanical component of the sensor is structurally related to the sensing component: the mechanical component of the sensor comprises an annular groove rotating disk 1 and a fitting annular groove fixing disk 40, and the sensing component of the sensor comprises a plurality of permanent magnet blocks 2 and a Hall 3 , the single chip microcomputer 31, the digital-to-analog converter 27 and the operational amplifier 28; four electronic components of the Hall 3, the single chip microcomputer 31, the digital-to-analog converter 27 and the operational amplifier 28 which are sequentially connected in the sensing unit are disposed on a circuit board 59; The annular groove of the hollow ring 41 rotates the inner wall of the disk 1 to fix a plurality of permanent magnet blocks 2, and the inner wall of the annular groove fixing plate 40 of the hollow ring 41 fixes the circuit board 59.
- the Hall 3 on the circuit board 59 is set to be able to feel the permanent magnet.
- the magnetic flux of block 2, and the Hall 3 can output the position of the varying electrical signal in accordance with the change in the magnetic flux.
- the sensing component is the sensing function of the sensor; the mechanical component has two functions. The first is to fix the relative position of each component in the sensing component, so that each component can form a sensing functional whole, and the second is to This sensing function is fixed on the electric bicycle as a whole, and makes the sensing function as a whole to sense the movement state of the electric bicycle.
- the four electronic components of the sequentially connected Hall 3, the single chip microcomputer 31, the digital-to-analog converter 27 and the operational amplifier 28 are arranged on a circuit board 59, which is advantageous for integration, modularization and miniaturization of the four electronic components.
- the four electronic components are integrally fixed to the inner wall of the annular groove fixing disk 40 of the hollow ring 41, which simplifies the process of manufacturing the sensor.
- Hall 3 is UGN3075
- power model processor 21 is AT89S52 single chip
- digital to analog converter 27 is ADC-C8E
- operational amplifier 28 is OF-17F
- OF A thermistor R6 is connected between the input terminal 2 of the -17F operational amplifier 28 and the output terminal 6; the connection relationship of each component is as follows:
- the signal output terminal 3 of Hall 3 is connected to the 12-pin INTO [P32] of the single chip microcomputer 31 ;
- MCU 31's 39-pin P00 is connected to the digital-to-analog converter 27's 12-pin B8;
- Mp 31 of the MCU 31 pin P01 is connected to the digital-to-analog converter 27 of the 11-pin B7;
- MCU 31's 37-pin P02 is connected to the digital-to-analog converter 27's 10 feet B6;
- the 36-pin P03 of the MCU 31 is connected to the 9-pin B5 of the digital-to-analog converter 27;
- MCU 31's 35-pin P04 is connected to the digital-to-analog converter 27's 8-pin B4;
- the 34-pin P05 of the MCU 31 is connected to the 7-pin B3 of the digital-to-analog converter 27;
- the 32-pin P06 of the MCU 31 is connected to the 6-pin B2 of the digital-to-analog converter 27;
- the 32-pin P07 of the single chip microcomputer 31 is connected to the 5-pin B1 of the digital-to-analog converter 27;
- the 4 pin of the digital-to-analog converter 27 is connected to the 2 pin of the operational amplifier 28;
- the 2-pin of the digital-to-analog converter 27 is connected to the 3 pin of the operational amplifier 28;
- the 6th pin of the operational amplifier 28 is the analog signal output.
- the OF-17F operational amplifier 28 has a thermistor R6 connected to the input pin 2 and the output pin 6 and a capacitor C6 connected in parallel with the thermistor R6.
- the thermistor R6 is 5K
- the capacitor C6 is 8 ⁇
- the 4 pin of the digital-to-analog converter 27 and the 2 pin of the operational amplifier 28 are grounded by 1.25k R5.
- the analog signal voltage range of the 286 pin output is stable between 0.8--4.2V.
- a bearing 42 is provided between the outer surface of the inner ring of the annular groove fixing disk 40 and the inner surface of the inner ring of the annular groove rotating disk 1.
- the bearing 42 maintains a good relative rotation between the annular groove fixing disk 40 and the annular groove rotating disk 1 for a long time.
- the Hall 3 is disposed between the inner circular track line and the outer circular track line. Since the Hall 3 is a component that can sense the magnetic flux of the permanent magnet block 2 and output an electric signal, and in order to minimize the volume of the permanent magnet block 2, the permanent magnet block is placed as much as possible on the annular groove rotating disk 1. 2, the permanent magnet block 2 can be induced to be induced by the Hall 3; the Hall 3 should be set between the inner circular track line and the outer circular track line, and preferably placed close to all permanent magnets The position of the circular trajectory of block 2.
- the annular groove rotating disk 1 is centered in a circle in which the inner circular trajectory of the plurality of permanent magnet blocks 2 is located. If the annular groove rotating disk 1 is to be worn over a rotating shaft, the annular groove rotating disk 1 is provided with a hole for threading the rotating shaft; to ensure that the annular groove rotates the disk 1 while rotating with the rotating shaft, The Hall 3 can sense the motion signal of each permanent magnet block 2 on the rotating disk 1 of the annular groove, and the through hole on the rotating disk 1 of the annular groove should be disposed in the inner circular trajectory of the plurality of permanent magnet blocks 2.
- the center of the circle range, because the inner circular trajectory line and the outer circular trajectory line are concentric circles, of course, the through hole is at the center of the circle circle where the outer circular trajectory line is located, and the through hole is the inner circular trajectory line and the outer circular trajectory.
- the center of the line is the hole, the center. That is to say, the center is not necessarily a circle, and may be a square, a triangle or the like so as to be able to be fitted with a rotating shaft of a shape such as a square or a triangle, but the inner space of the center must include the center of the circle in which the inner circular trajectory line is located. It is only possible to use a Hall 3 to sense the motion signal of all the permanent magnet blocks 2 on the rotating disk of the circular groove rotating disk 1 by the annular groove.
- the magnetic flux of at least one of the permanent magnet blocks 2 is not equal to the magnetic flux of any of the other permanent magnet blocks 2.
- special magnetic flux can be used to indicate the position of the bicycle pedal.
- the magnetic flux of at least two of the permanent magnet blocks 2 is not equal to the magnetic flux of any one of the other permanent magnet blocks 2, and the two special magnetic flux permanent magnet blocks 2 correspond to two foot pedals, respectively, for indicating two bicycles The position of the foot pedal. Because of the circular motion of the bicycle pedal, it is important to determine the speed of the pedal motion in order to obtain the speed of the current circular motion.
- the annular groove rotating disk 1 is a plastic plate, an aluminum plate, or a copper plate of a non-magnetic material. Since the present invention is a structure in which the magnetic polarities of the adjacent permanent magnet blocks 2 are opposite to each other, the edges of the adjacent permanent magnet blocks 2 can be made to be close to each other, and the Hall 3 can output an electric signal having a control function.
- the invention has the advantages of simple structure, low cost, unlimited number of permanent magnet blocks on the permanent magnet block ring, output of standard pulse signals, no signal dead zone, and complete representation of only one Hall of output signals.
- the output signal will not be distorted and not drifted, the magnetic flux change of the permanent magnet block indicates the fixed position, and the output signal can have the moving position of each permanent magnet block, which is used to assist the bicycle to make the power output and The driver's needs are highly compatible and the rider feels comfortable.
- the magnetic polarity is opposite, output rectangular wave signal, with precise control function: Since the magnetic polarity of the adjacent permanent magnet block is opposite, and Hall selects the Hall which produces the rectangular wave output signal to the opposite magnetic polarity, the adjacent permanent magnet Regardless of the spacing of the blocks, Hall can output a rectangular wave signal even if there is no gap between adjacent permanent magnet blocks.
- Hall can output a rectangular wave signal even if there is no gap between adjacent permanent magnet blocks.
- the position and speed of the bicycle pedal are assisted to calculate the correct power demand for the sporty state with the precise position and speed of the pedal.
- the magnetic polarity of adjacent permanent magnet blocks is opposite, and the number of permanent magnet blocks is not limited.
- the sensing points can be increased as much as possible: Since the magnetic polarity is opposite, the rectangular wave signal is output, and the adjacent permanent magnet blocks have no gap even if they are The output signal is still a number, distinguishable rectangular wave signal, and still has a control function, that is, it does not output a non-changing linear signal without control function.
- the number of permanent magnets can be increased as much as possible on the rotating disk of the ring groove of a predetermined size, and the sensing point can be increased as much as possible. As many sensor signals as possible indicate the position and speed of the bicycle pedal movement, accurately indicating the motion state.
- the magnetic polarity of adjacent permanent magnet blocks is opposite. There may be more permanent magnet blocks and more sensing points.
- the motion state of the rotating disk of the annular groove is accurate: for the bicycle used to assist the bicycle, the ring of the permanent magnet block is fixed.
- the size of the rotating disk of the groove is strictly limited. Generally, the diameter of the rotating disk of the annular groove can only be within 10-15 cm. In order for the Hall to obtain the magnetic pole signal of the permanent magnetic block under the condition of spacing, the diameter of the permanent magnetic block is at least For the ⁇ 0. 6-0.
- the adjacent permanent magnet blocks have the same magnetic polarity, the adjacent permanent magnet blocks are spaced by 5 cm, and on the rotating disk of the diameter of 10-15 cm, only 5-8 permanent magnets can be set.
- the motor control accuracy of the assist bicycle is naturally increased by 7-9 times, which makes the rider's assistance demand accuracy also improved by 7-9 times.
- the degree of cooperation between the vehicle and the person is greatly improved, and the rider's comfort is greatly increased. It is no longer a quick and uncomfortable feeling of the prior art moped.
- this patent can set up to 35-73 permanent magnet blocks around the ring groove rotating disk with a diameter of 10-15 cm. The average angle between them is 5-10 degrees.
- the pedals used to assist bicycles, when starting or running, the pedals have 4-7 permanent magnet blocks from a range of 10 degrees from the apex of 10-45 degrees (a signal at a 10 degree angle from the apex) ), Hall can output 4-7 control signals to respond to the power demand, and it can achieve excellent technical effects that can be obtained at any position and at any time with help, so that the car and people can cooperate well, and the rider feels labor-saving. Comfortable.
- Only one Hall is used.
- One control signal indicates the entire motion state of the rotating disk of the ring groove.
- the control signal is completely consistent with the motion state of the rotating disk of the ring groove.
- the control signal is exactly the same as the human demand:
- the block is fixed on the rotating disk of the annular groove, and the permanent magnet block rotates synchronously with the rotating disk of the annular groove, and the motion signal of all the permanent magnetic blocks is sensed by one Hall, and the control signal of the Hall output and the rotating groove of the annular groove are rotated.
- the motion state is completely consistent, and the human demand is exactly the same, and the control signal does not have the original segmentation error and signal drift problem. Even if the Hall sensing parameter changes, the entire control signal moves in parallel.
- each permanent magnet block makes the Hall output have a unique peak-to-valley difference.
- the control signal of the value waveform, the control signal of the unique peak-to-valley difference waveform can directly represent the motion state of a fixed permanent magnet block position of the circular groove rotating disk; for example, each permanent magnet block has its own specific magnetic flux How many permanent magnet blocks can be reached, and how many motion state signals of specific sites can be obtained.
- the diameter of the ring groove is within 10-15 cm, and the ring groove rotates for one turn.
- the Hall can obtain 35-73 control signals of different position motions, naturally knowing 35-73
- the circular groove rotates the disk one turn, the prior art can only have a maximum of 5-8 power demand, far less than the 35-73 power demand signal of this patent can be more realistic and multi-informative reaction
- the support of the rider That is to say, the bicycle is equipped with the patented technology, and the vehicle can be matched with the needs of the person. The rider feels that the pedal is in any rotational position, and the vehicle can fully control the speed and comfort.
- the prior art assist bicycle can only control the vehicle speed in a maximum of 5-8 rotation positions.
- the Hall signal can be digitized, and the control signal can be added to the control model with the best cooperation of the human machine: the rectangular wave signal with the magnetic block position and the magnetic block rotational speed is changed into the digital signal of the two elements, and the design is used.
- the mathematical power-assisted model suitable for human-machine coordination converts the digital signals of the two elements into the digital signal of the power-assisted model, converts the digital signal of the power-assisted model into the analog signal of the power-assisted model, and finally turns the analog signal of the power-assisted model into a stable voltage range.
- Control signals available for motor controllers with rated power In short, the signal of the rotation of the magnetic block is digitized.
- a mathematical assist model is added, so that the control signal finally outputted by the sensor contains the added assisting model. Since the mathematical assist model is artificially set, the mathematical assist model can always be set to the model most suitable for human-machine coordination.
- the sensor of the present invention can output a control signal that can achieve the best human-machine coordination.
- the magnetic poles of the existing bicycle sensor have the same magnetic pole on the same side, and the Hall cannot obtain the rectangular wave signal, so the Hall signal cannot be digitized.
- the control model can only partially modify the Hall signal, so it cannot A control signal that achieves the best fit of the output man-machine.
- the final output control signal will not have signal drift: Using the thermistor R6 to feedback adjust the output signal of the operational amplifier, it can solve the drift of the analog model analog signal by semiconductor devices such as Hall, digital-to-analog converter and operational amplifier. The problem is that the sensor finally outputs a standard boost model analog signal that is not subject to ambient temperature changes.
- Fig. 1 is a schematic view showing the structure of a sensing element in which the magnetic flux of the multi-magnetic block on the rotating disk of the annular groove is unevenly distributed, and the permanent magnet block N-S alternates, and the difference in the thickness of the permanent magnet block indicates that the magnetic flux is different;
- Fig. 2 is a schematic view showing the structure of the sensing element of the N-S alternating magnetic flux of the multi-magnetic block on the rotating disk of the annular groove, and the difference of the thickness of the permanent magnet block in the figure indicates that the magnetic flux is different;
- Figure 3 is a schematic cross-sectional view of the sensor
- FIG. 4 is a block diagram of signal flow of a Hall, a power assist model processor, a digital to analog converter, and an operational amplifier;
- Figure 5 is a circuit diagram of a Hall, a microcontroller, a digital-to-analog converter, and an operational amplifier.
- 1 is an annular groove rotating disk
- 2 is a permanent magnet block
- 3 is a Hall
- 5 is a circular trajectory line
- 21 is a power assist model processor
- 22 is an analog-to-digital conversion and a peak recognizer
- 23 is a boosting starting point selection.
- 24 is the magnetic block speed calculator
- 25 is the boost model memory
- 26 is the boost model calculator
- 27 is the digital-to-analog converter
- 28 is the operational amplifier
- 29 is the motor control
- 30 is the motor
- 31 is the single chip microcomputer
- 32 is the clock circuit
- 40 is the annular groove fixed disk
- 41 is the hollow ring
- 42 is the bearing
- 59 is the circuit board.
- Embodiment 1 A sensor for distributing magnetic flux in a plurality of magnetic blocks in a casing
- the sensor of this embodiment comprises a sensing element, a boosting model processor 21, a digital-to-analog converter 27 and an operational amplifier 28;
- the sensing element is an element that changes the rotational motion of the annular groove rotating disk 1 into a rectangular wave signal output
- the annular groove rotating disk 1 and the annular groove fixing disk 40 are sized so that the annular groove fixing disk 40 can be fitted in the ring shape.
- the concave groove rotates the annular groove of the disk 1 to form a fitting inner hollow outer casing of two disks, the concave surfaces of the two disks are sandwiched into a hollow ring 41; the annular groove at the position of the hollow ring 41 rotates the disk 1
- the annular groove rotating disk 1 and the annular groove fixing disk 40 are injection molded from high-strength plastic.
- the magnetic flux is 0. 8cm, the magnetic flux is 0. 8cm, the magnetic flux is 0. 8cm, the magnetic flux is 0. 8cm, the magnetic flux is 0. 8cm, the magnetic flux It is a different selection value in the range of 146---279(B ⁇ H)max/KJ ⁇ m" 3 , and the magnetic flux of the adjacent permanent magnet block 2 is not equal.
- the annular groove rotates the disk 1, the permanent magnet block 2, Huo
- the structure of 3 is as follows:
- All the permanent magnet blocks 2 are distributed in a circular trajectory, and each permanent magnet block 2 is fixed on a circular trajectory line 5 having a diameter of 9.0 cm, that is, the distance from the center of each circular portion of the permanent magnet block 2 to the circular trajectory line 5. The distance between the same, adjacent permanent magnet blocks 2 is the same.
- the magnetic flux of the two permanent magnet blocks 2 is not equal to the magnetic flux of any other permanent magnet block 2, and the two permanent magnet blocks
- the magnetic fluxes of 2 are also not equal.
- the positions of the two permanent magnet blocks 2 are exactly at the ends of one diameter of the annular groove rotating disk 1, and the two permanent magnet blocks 2 are used to represent two footboards on the assist bicycle. Sports position.
- All the permanent magnet blocks 2 disposed on one surface of the annular groove rotating disk 1 are arranged in such a manner that the magnetic polarities of the adjacent permanent magnetic blocks 2 are opposite, that is, the magnetic polarity distribution of all the permanent magnet blocks 2 on one surface of the annular groove rotating disk 1
- the method is N pole, S pole, N pole, S pole, N pole, S pole ⁇ .
- a Hall 3 is fixedly disposed on the annular groove fixing plate 40 in the hollow ring 41.
- the signal output line of the Hall 3 passes through the annular groove fixing plate 40, and the Hall 3 is disposed close to the permanent magnet block 2.
- the Hall 3 is disposed in the range of the circular trajectory line 5 where each of the permanent magnet blocks 2 is located, and the Hall 3 maintains a distance of 0.3 cm from each of the permanent magnet blocks 2 in the rotating state, so that each permanent magnet block that rotates 2 When passing through Hall 3, Hall 3 can generate a corresponding rectangular wave electrical signal output.
- the annular groove rotating disk 1 is centered at the center of the circular trajectory line 5 where the permanent magnetic block 2 is located, and the center is used for the pedal middle shaft or the rotating shaft of the assist bicycle.
- the assist model processor 21 is a converter that converts the digital signal of the circular groove rotating disk 1 into a signal form of the assist model digital signal;
- the assist model processor 21 includes an analog to digital conversion and peak recognizer 22, a boost start point selector 23, a magnetic block tachometer 24, a boost model memory 25, and a boost model calculator 26;
- the analog-to-digital conversion and peak identifier 22 is connected to the sensing element, and the analog-to-digital conversion and peak identifier 22 recognizes the rectangular wave signal input from the Hall 3 in the sensing element to identify the peak of each rectangular wave, and changes each rectangular wave signal into Different digital signals are labeled for each rectangular wave, and the analog-to-digital conversion and peak identifier 22 outputs a magnetic block motion digital signal marked with a magnetic block position order;
- the analog-to-digital conversion and peak recognizer 22 is connected to the assist start point selector 23 and the magnetic block rotational speed calculator 24, respectively, and the boost start point selector 23 is connected to the magnetic block rotational speed calculator 24; the magnetic block rotational speed calculator 24 uses analog-to-digital conversion and peaks.
- the digital signal of the magnetic block movement input by the identifier 22 calculates the rotational speed of the circular groove rotating disk 1, and transmits the digital signal of the rotational speed of the circular groove rotating disk 1 to the assisting start point selector 23, and the assisting start point selector 23 is marked with magnetic
- the digital signal of the magnetic block movement of the block position order and the digital signal of the rotational speed of the circular groove rotating disk 1 determine a rectangular wave corresponding to the starting point of the assisting force under a certain rotational speed condition, that is, the starting point magnetic block is determined;
- the starting point selector 23 completes the finding of the starting point of the boosting magnetic block, that is, determines the starting of the assisting force from a certain rectangular wave, which is precisely the rotation of the disk 1 at a certain rotational speed condition, from a certain magnetic block Start a boost at a certain position, or start from a certain position at a certain magnetic block, and change the original power assist model to the power assist model selected in the next step. Help.
- the assist starting point selector 23 and the magnetic block rotational speed calculator 24 are respectively connected to the assist model calculator 26, and the assist model memory 25 is also connected to the assist model calculator 26; the assist model calculator 26 uses the assist starting point of the assist starting point selector 23 The block, and the rotational condition of the disk 1 by the annular groove of the magnetic block rotational speed calculator 24, selects one of the assist model functions in the assist model memory 25, and rotates the starting magnetic block and the annular groove to rotate the disk 1 These two conditions are substituted into the assist model function to calculate the assist model digital signal suitable for these two conditions, that is, the assist model calculator 26 outputs the assist model digital signal;
- the digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model.
- the assist model calculator 26 is connected to the digital-to-analog converter 27, which converts the assist model digital signal of the assist model calculator 26 into a boost model analog signal. In order to output an analog signal of the assist model to the motor controller 29 which can only process the analog signal.
- the operational amplifier 28 is a boost model analog signal that converts the assist model analog signal of the digital-to-analog converter 27 into a rated voltage range.
- the digital-to-analog converter 27 is connected to the operational amplifier 28.
- the power-assisted model analog signal of the digital-to-analog converter 27 solves the power-assisted model problem, but the voltage of the power-assisted model signal cannot meet the needs of the motor controller 29, so it is also used.
- the operational amplifier 28 converts the assist model analog signal into a boost model analog signal required for the rated voltage range, and can be transmitted to the motor controller 29 to achieve the purpose of the motor controller 29 controlling the motor 30 for the purpose of assisting.
- Embodiment 2 A sensor with high density and uneven magnetic flux distribution in a housing
- the annular groove in the hollow ring 41 rotates the disk 1 surface diameter of 10.
- the ring groove rotating disk 1 is set 40 permanent magnet blocks 2, 40 permanent magnet blocks 2 diameter respectively
- the magnetic flux is different from the range of 146-279 (B ⁇ H) max / KJ ⁇ m" 3 , and the magnetic flux of the adjacent permanent magnet block 2 is not equal.
- Hall 3 and the rotating state Each permanent magnet block 2 maintains a separation distance of 0.2 cm, so that each of the rotating permanent magnet blocks 2 can generate a corresponding rectangular wave electric signal output when passing through the Hall 3.
- Other annular groove rotating disk 1 The structure of the permanent magnet block 2 and the Hall 3 is the same as that of the embodiment 1.
- Embodiment 3 A sensor with a specific circuit for distributing magnetic flux in a multi-magnetic block in a housing
- the sensor of the embodiment comprises a sensing element, a boosting model processor 21, a digital-to-analog converter 27 and an operational amplifier 28;
- Hall 3 in the sensing element is UGN3075; the other components and components in the sensing element have the same structure as in Embodiment 1;
- Power model processor 21 Selecting the single-chip microcomputer 31 to complete all functions, the single-chip 31 selects AT89S52. That is, the AT89S52 MCU 31 performs all functions of the analog-to-digital conversion and peak recognizer 22, the assist start point selector 23, the magnetic block rotational speed calculator 24, the assist model memory 25, and the assist model calculator 26.
- Digital-to-analog converter 27 uses ADC-C8E.
- the operational amplifier 28 selects OF-17F, the OF-17F operational amplifier 28 has a 5k thermistor R6 connected between the input 2 pin and the output 6 pin; and the thermistor R6 is also connected with 8P capacitor in parallel. C6.
- the 4 pin of the digital-to-analog converter 27 is grounded to the 2 pin of the operational amplifier 28 with 1.25k of R5. It can be used with thermistor R6 to adjust the operational amplifier.
- the analog signal voltage range of the 286 pin output is stable between 0.8--4.2V.
- connection relationship of each electronic component is as follows:
- the signal output terminal 3 of Hall 3 is connected to the 12-pin INTO [P32] of the single chip microcomputer 31 ;
- MCU 31's 39-pin P00 is connected to the digital-to-analog converter 27's 12-pin B8;
- Mp 31 of the MCU 31 pin P01 is connected to the digital-to-analog converter 27 of the 11-pin B7;
- MCU 31's 37-pin P02 is connected to the digital-to-analog converter 27's 10 feet B6;
- the 36-pin P03 of the MCU 31 is connected to the 9-pin B5 of the digital-to-analog converter 27;
- MCU 31's 35-pin P04 is connected to the digital-to-analog converter 27's 8-pin B4;
- the 34-pin P05 of the MCU 31 is connected to the 7-pin B3 of the digital-to-analog converter 27;
- the pin 33 of the single chip 31 is connected to the 6 pin B2 of the digital to analog converter 27;
- the 32-pin P07 of the single chip microcomputer 31 is connected to the 5-pin B1 of the digital-to-analog converter 27;
- the 4-pin of the digital-to-analog converter 27 is connected to the 2 pin of the operational amplifier 28;
- the 2-pin of the digital-to-analog converter 27 is connected to the 3 pin of the operational amplifier 28;
- the 6th pin of the operational amplifier 28 is the analog signal output.
- the mechanical component of the sensor comprises an annular groove rotating disk 1 and a fitting annular groove fixing disk 40
- the sensing component of the sensor comprises a plurality of permanent magnet blocks 2 Hall 3, single chip microcomputer 31, digital to analog converter 27 and operational amplifier 28
- four electronic components of Hall 3, single chip microcomputer 31, digital to analog converter 27 and operational amplifier 28 which are sequentially connected in the sensing unit are provided on one circuit board 59
- a plurality of permanent magnet blocks 2 are fixed on the inner wall of the annular groove rotating disk 1 of the hollow ring 41, and the circuit board 59 is fixed on the inner wall of the annular groove fixing disk 40 of the hollow ring 41.
- the Hall 3 on the circuit board 59 is disposed in the upper wall.
- the magnetic flux of the permanent magnet block 2 is sensed, and the Hall 3 can output the position of the varying electrical signal according to the change in the magnetic flux.
- the sensing component is the sensing function of the sensor; the mechanical component has two functions. The first is to fix the relative position of each component in the sensing component, so that each component can form a sensing functional whole, and the second is to This sensing function is fixed on the electric bicycle as a whole, and makes the sensing function as a whole to sense the movement state of the electric bicycle.
- the four electronic components of the sequentially connected Hall 3, the single chip microcomputer 31, the digital-to-analog converter 27 and the operational amplifier 28 are arranged on a circuit board 59, which is advantageous for integration, modularization and miniaturization of the four electronic components.
- the four electronic components are integrally fixed to the inner wall of the annular groove fixing disk 40 of the hollow ring 41, which simplifies the process of manufacturing the sensor.
Landscapes
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Electromagnetism (AREA)
- Engineering & Computer Science (AREA)
- Theoretical Computer Science (AREA)
- Measurement Of Length, Angles, Or The Like Using Electric Or Magnetic Means (AREA)
- Transmission And Conversion Of Sensor Element Output (AREA)
Abstract
Description
Claims
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
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IN1070DEN2015 IN2015DN01070A (zh) | 2012-07-28 | 2013-06-05 | |
US14/417,790 US9429449B2 (en) | 2012-07-28 | 2013-06-05 | Sensor having multiple magnetic blocks of unevenly distributed magnetic fluxes in housing |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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CN201210263503.9A CN102785743B (zh) | 2012-07-28 | 2012-07-28 | 在壳体内多磁块不均匀分布磁通量的传感器 |
CN201210263503.9 | 2012-07-28 |
Publications (1)
Publication Number | Publication Date |
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WO2014019405A1 true WO2014019405A1 (zh) | 2014-02-06 |
Family
ID=47151363
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PCT/CN2013/076773 WO2014019405A1 (zh) | 2012-07-28 | 2013-06-05 | 在壳体内多磁块不均匀分布磁通量的传感器 |
Country Status (4)
Country | Link |
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US (1) | US9429449B2 (zh) |
CN (1) | CN102785743B (zh) |
IN (1) | IN2015DN01070A (zh) |
WO (1) | WO2014019405A1 (zh) |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102785743B (zh) * | 2012-07-28 | 2014-02-05 | 成都宽和科技有限责任公司 | 在壳体内多磁块不均匀分布磁通量的传感器 |
DE102015113735A1 (de) * | 2015-08-19 | 2017-02-23 | Polyresearch Ag | Sensorvorrichtung, antriebssystem, verfahren zum messen eines drehmoments und verfahren zum regeln eines antriebssystems |
CN111900961A (zh) * | 2020-08-24 | 2020-11-06 | 国网山东省电力公司滨州市沾化区供电公司 | 一种波形信号发生器 |
CN114071920B (zh) * | 2021-11-16 | 2023-03-21 | 南通茂业电子科技有限公司 | 一种带有退磁预警提示的电永磁吸盘控制器组件 |
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- 2013-06-05 US US14/417,790 patent/US9429449B2/en not_active Expired - Fee Related
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- 2013-06-05 IN IN1070DEN2015 patent/IN2015DN01070A/en unknown
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Also Published As
Publication number | Publication date |
---|---|
US9429449B2 (en) | 2016-08-30 |
CN102785743A (zh) | 2012-11-21 |
CN102785743B (zh) | 2014-02-05 |
US20150211893A1 (en) | 2015-07-30 |
IN2015DN01070A (zh) | 2015-06-26 |
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