WO2014019412A1 - Power-assist bicycle using sensor having multiple magnetic blocks of unevenly distributed magnetic fluxes in housing - Google Patents

Power-assist bicycle using sensor having multiple magnetic blocks of unevenly distributed magnetic fluxes in housing Download PDF

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Publication number
WO2014019412A1
WO2014019412A1 PCT/CN2013/076819 CN2013076819W WO2014019412A1 WO 2014019412 A1 WO2014019412 A1 WO 2014019412A1 CN 2013076819 W CN2013076819 W CN 2013076819W WO 2014019412 A1 WO2014019412 A1 WO 2014019412A1
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WIPO (PCT)
Prior art keywords
annular groove
digital
signal
permanent magnet
power
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PCT/CN2013/076819
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French (fr)
Chinese (zh)
Inventor
黄强
Original Assignee
高松
欧阳焱雄
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Application filed by 高松, 欧阳焱雄 filed Critical 高松
Publication of WO2014019412A1 publication Critical patent/WO2014019412A1/en

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING 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
    • G01D5/00Mechanical 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
    • G01D5/12Mechanical 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
    • G01D5/244Mechanical 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
    • G01D5/245Mechanical 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
    • G01D5/2451Incremental encoders
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B62LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
    • B62MRIDER PROPULSION OF WHEELED VEHICLES OR SLEDGES; POWERED PROPULSION OF SLEDGES OR SINGLE-TRACK CYCLES; TRANSMISSIONS SPECIALLY ADAPTED FOR SUCH VEHICLES
    • B62M6/00Rider propulsion of wheeled vehicles with additional source of power, e.g. combustion engine or electric motor
    • B62M6/40Rider propelled cycles with auxiliary electric motor
    • B62M6/45Control or actuating devices therefor
    • B62M6/50Control or actuating devices therefor characterised by detectors or sensors, or arrangement thereof
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B62LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
    • B62MRIDER PROPULSION OF WHEELED VEHICLES OR SLEDGES; POWERED PROPULSION OF SLEDGES OR SINGLE-TRACK CYCLES; TRANSMISSIONS SPECIALLY ADAPTED FOR SUCH VEHICLES
    • B62M6/00Rider propulsion of wheeled vehicles with additional source of power, e.g. combustion engine or electric motor
    • B62M6/40Rider propelled cycles with auxiliary electric motor
    • B62M6/60Rider propelled cycles with auxiliary electric motor power-driven at axle parts
    • B62M6/65Rider propelled cycles with auxiliary electric motor power-driven at axle parts with axle and driving shaft arranged coaxially

Definitions

  • the invention belongs to the technical field of assisting bicycles, in particular to an electric assist bicycle which performs multi-point magnetic induction on a rotating component and provides a power assist signal.
  • 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 Hall-sensing area it is possible to increase the number of permanent magnet blocks as much as possible, to maximize the use of bicycle pedal displacement information, and to accurately position the sensor output information.
  • the sensor uses one assembly to fix the Hall and multiple permanent magnet blocks.
  • the relative position of the assisted bicycle; on the use of the assisted bicycle, the assisting demand of the rider is well matched with the assist provided by the motor, and the motor runs smoothly to assist the bicycle.
  • 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 sensing element connected in sequence, a boost 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 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, and the annular groove rotating disk 1 and the annular groove fixing disk 40 are concavely opposed to each other,
  • the annular groove fixing plate 40 is fitted in the annular groove of the annular groove rotating disk 1, and the two disks can be relatively rotated to fit the hollow inner casing, and the concave surfaces of the two disks are sandwiched into a hollow ring 41;
  • the annular groove rotating disk 1 at the position of the ring 41 is fixedly provided with a plurality of permanent magnet blocks 2, and the plurality of permanent magnet blocks 2 are distributed in a circular trajectory, that is, each permanent magnet block 2 to a circular trajectory line 5
  • the distance between the centers of the circles is the same, the distance between the adjacent permanent magnet blocks 2 is the same; the magnetic polarity of the adjacent permanent magnet blocks 2 is opposite, and the magnetic polarity distribution pattern of all the permanent magnet blocks 2 on the rotating disk 1 of the annular
  • a Hall 3 is fixedly disposed on the annular groove fixing plate 40 of the hollow ring 41.
  • the Hall 3 is disposed near the permanent magnet block 2 and can sense the magnetic flux of each permanent magnet block 2, and the Hall 3 and the permanent magnet block There is a gap between 2;
  • Hall 3 is a Hall that produces 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 start point selector 23 and the magnetic block rotational speed calculator 24 are respectively connected to the assist model calculator 26, and the assist mode
  • the type memory 25 is also connected to the assist model calculator 26;
  • the boost model calculator 26 is selected by the assist starting point magnet block of the assist starting point selector 23, and the rotational speed of the disc 1 by the annular groove of the magnetic block rotational speed calculator 24.
  • the assist model calculator 26 outputs 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 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.
  • connection relationship between the sensor and the electric bicycle is: the annular groove rotating disk 1 of the sensor and the annular groove fixing plate 40 are sleeved outside the middle shaft 51 of the electric bicycle, and the annular groove fixing plate 40 and the sleeve 52 outside the middle shaft 51
  • the fixed connection, the annular groove rotating disk 1 of the sensor is fixedly connected with the central shaft 51 of the electric bicycle, the annular groove rotating disk 1 is synchronously rotated with the central shaft 51; the annular groove rotating disk 1 and the annular groove fixing plate 40 are arranged inside and outside.
  • the fitting is a rotational connection; both the annular groove rotating disk 1 and the central axis 51 are the same center of rotation, and the signal output wire of the operational amplifier 28 in the sensor is connected to the signal input terminal of the motor controller 29 of the electric bicycle.
  • the description of the working principle of the sensor is divided into signal acquisition and signal processing, in order to explain the structural relationship and function of each component of the sensor.
  • the signal acquisition is performed by the annular groove rotating disk 1, the annular groove fixing disk 40, the permanent magnetic block 2 and the Hall 3 of the sensing element to perform a function of acquiring signals;
  • the signal processing is performed by the assist model processor 21, digital-to-analog conversion
  • the comparator 27 and the operational amplifier 28 are sequentially connected to process the signal output from the Hall 3 into an assist model analog signal that can be used by the motor controller 29 of the electric bicycle.
  • 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 alternate south and north. Facing the Hall 3, the Hall 3 generates an electric signal as a rectangular wave signal, and the rectangular wave signal is convenient for digitizing the signal 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 groove of the annular groove, or each of the movement states of the permanent magnet block 2. For example, when it is 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. Because the peak-to-valley value of the rectangular wave signal changes for a short period of time, as many controlled 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.
  • Panyi Generally, the diameter is 10-15 cm. In this range, a signal with control function is obtained, and one rotation is made, and the rectangular wave is generated 7-9 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 assisting bicycle, and the person and the vehicle 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 and functions of the components in the power model processor 21 are 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 by 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 transmitting the digital signal of the rotational speed of the annular groove rotating disk 1 to the assisting start point selector 23, the boosting starting point selector 23 uses the magnetic block moving digital signal marked with the position of the magnetic block, and the rotational speed digital signal of the circular groove rotating disk 1.
  • the starting point magnetic block determines 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. 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 assist model digital signal suitable for these two conditions, that is, the assist model calculator 26 can output 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 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 senor is divided into a mechanical component and a sensing component from the physical aspect to illustrate the structural relationship between each physical object of the sensor and the physical object of the electric bicycle.
  • the mechanical component is in a rotationally coupled relationship by the annular groove rotating disk 1 and the annular groove fixing disk 40, and is formed into a ring-shaped inner casing structure.
  • the shell is enclosed in the air a plurality of permanent magnet blocks 2 of the sensing member are fixed on the inner surface of the annular groove rotating disk 1 in the annular inner space of the casing, and the permanent magnet block 2 rotates synchronously with the annular groove rotating disk 1 to make a plurality of permanent magnets
  • the block 2 rotates in synchronism with the bicycle footrest 54 to achieve the purpose of using the plurality of permanent magnet blocks 2 to represent the cyclist's mechanical action for the assisting demand.
  • the Hall 3 of the sensing member, the assist model processor 21, the digital-to-analog converter 27 and the operational amplifier 28 are fixed to the inner surface of the annular annular groove fixing disk 40 in the annular inner casing of the casing, the annular groove fixing plate 40 and the bicycle frame
  • the sleeve 52 is fixed so that the annular groove fixing plate 40 does not rotate with the annular groove rotating disk 1
  • the sensing member Hall 3, the assist model processor 21, and the digital-to-analog converter 27 are fixed on the annular groove fixing plate 40.
  • the operational amplifier 28 does not rotate with the annular groove rotating disk 1, so that the Hall 3 can sense the rotational position of all the permanent magnet blocks 2 with a fixed position, so that the cyclist's mechanical action for the power demand can be turned into electricity.
  • the signal through the sensing component, assists the model processor 21, the digital-to-analog converter 27, and the operational amplifier 28, and changes the power demand signal of the Hall 3 into a power-assisted model electrical signal that is matched by the human-machine, and the operational amplifier 28 matches the human-machine.
  • the power signal of the power-assisted model is transmitted to the motor controller 29, and the motor controller 29 controls the motor 30 to rotate in a matching manner of the human-machine, and finally realizes that the power-assisted bicycle moves according to the best demand of the person, that is, Human-computer matching results.
  • 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 outer surface of the annular groove fixing plate 40 of the sensor is provided with a circular recess 58; the circular recess 58 is engaged with the sleeve 52 outside the shaft 51 of the electric bicycle, and the sleeve 52 is sleeved and fixedly connected in the circular recess 58. .
  • the circular recess 58 of the fixing plate 40 is fixed to the sleeve 52 outside the shaft 51 of the electric bicycle, and has the advantages of simple assembly, convenient cleaning and beautiful appearance.
  • 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 provided with a center hole in a circle in which the inner circular track 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 hole. That is to say, the center hole is not necessarily circular, and may be a square, a triangle or the like so as to be sleeved with a rotating shaft of a shape such as a square or a triangle, but the inner space of the center hole must include the circle of the inner circular trajectory.
  • the center can use a Hall 3 to sense the motion signal of all the permanent magnet blocks 2 on the rotating disk of the annular groove rotating disk 1 to rotate the disk.
  • 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 Foot pedal position For obtaining the speed of this circular motion, it is important to determine the assist model for the next 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 entire motion state of the moving plate, 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, how many can be obtained?
  • the motion state signal of a specific site For the purpose of assisting the bicycle, 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-information reaction riding
  • 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 position of the magnetic block and the rotational speed of the magnetic block is changed into the digital signal of the two elements.
  • 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 problem that the semiconductor device such as Hall, digital-to-analog converter and operational amplifier makes the analog model drift signal.
  • the final output of the sensor is a standard boost model analog signal that is unaffected by ambient temperature changes.
  • the working mode of the motor that can achieve the best cooperation between man and machine the analog-to-digital conversion and the peak recognizer convert each rectangular wave signal into a different digital signal
  • the assist model calculator can be selected in the assist model memory by the assist starting point selector.
  • the assisted mathematical model that best matches the boosting demand, and the speed parameter provided by the magnetic block speed calculator is substituted into the assisting mathematical model, and the assist model calculator can calculate the assisting model number of the pedal in a certain position. signal.
  • the power model digital signal is a control signal for controlling the motor to best match the electric bicycle.
  • the power model calculator is a digital processor that can accept any digitized mathematical model.
  • the power model memory can provide any artificially set mathematical model to the power model calculator.
  • the assist bicycle of the present invention is a power-saving bicycle that is optimally matched with an electric bicycle.
  • Hall can only output less than 10 sine wave signals, and the sine wave signal cannot be converted into a digital signal. It is impossible to artificially add the optimal power model to control the electric bicycle motor.
  • the power assist model of the bicycle can not achieve the best fit of the man-machine, nor can the motor have the most reasonable and power-saving working mode.
  • the power-assisted bicycle of the present invention is compared with the commercially available power-assisted bicycle with the same magnetic pole as the sensing component on the same magnetic pole block, and the same electric bicycle is used for replacement.
  • the same rider rides on the same road section and the result is: After riding the 110 km of the assisted bicycle of the invention, the battery still has a small amount of electricity; but with the booster bicycle purchased in the city After riding for 45 kilometers, there is no battery left.
  • the significance of the power saving is that the fully-powered bicycle of the present invention can satisfy the whole day riding without charging, and solves the big problem that the bicycle is unable to assist the existing assist bicycle on the way.
  • 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;
  • FIG. 3 is a schematic cross-sectional structural view showing a relationship between a center axis of a bicycle and a sleeve and a 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;
  • Fig. 6 is a schematic view showing the connection relationship of the sensor provided on the center shaft of the electric bicycle to constitute the assist bicycle of the present invention.
  • 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 controller
  • 30 is the motor
  • 31 is the microcontroller
  • 32 Is the clock circuit
  • 40 is the annular groove fixed disk
  • 41 is the hollow ring
  • 42 is the bearing
  • 51 is the center shaft
  • 52 is the sleeve
  • 53 is the chain plate
  • 54 is the foot pedal
  • 55 is the battery
  • 58 is the circle
  • the recess, 59 is the circuit board.
  • Embodiment 1 A power bicycle with a magnetic flux sensor distributed unevenly by a multi-magnetic block in a casing 1, 3, 4, 6, the sensor of the present invention is mounted on the center shaft 51 of the existing electric bicycle, and the signal output line of the sensor is connected to the motor controller 29 of the electric bicycle, thereby obtaining the present invention. Power bicycles.
  • the electric bicycle has a middle shaft 51, the middle portion 51 has a sleeve 52 in the middle portion, and the middle shaft 51 is rotatably connected with the sleeve 52; the chain shaft 53 is fixed on the central shaft 51.
  • the inner shaft 51 is respectively fixed with a foot pedal 54; the inner surface of the sleeve 52 is rotatably connected with the central shaft 51, and the outer surface of the sleeve 52 is fixedly connected with the frame of the electric bicycle; the electric battery 55 is connected to the motor control
  • the motor controller 29 is coupled to the motor 30 on the wheel.
  • the sensor comprises a sensing element connected in sequence, a boost 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 permanent magnet blocks 2 are distributed in a circular trajectory, and each permanent magnet block 2 is fixed on a circular trajectory with a diameter of 9.0 cm.
  • 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 magnetic fluxes of the two permanent magnet blocks 2 are also not equal, and the positions of the two permanent magnet blocks 2 are exactly rotated in the annular groove.
  • the disk 1 has two ends of a diameter, and the two permanent magnet blocks 2 are used to indicate the moving position of the two foot pedals on the assist bicycle.
  • 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 modes are 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 is kept at a distance of 0.3 cm from each of the permanent magnet blocks 2 in the rotating state.
  • the Hall 3 can generate a corresponding rectangular wave electric signal output.
  • the annular groove rotating disk 1 is provided with a center hole at the center of the circular trajectory line 5 where the permanent magnetic block 2 is located, and the center hole is for fitting on the pedal center shaft 51 of the assist bicycle.
  • the assist model processor 21 is a converter that converts the digital signal rotated by the annular 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 booster that converts the assist model analog signal of the digital-to-analog converter 27 into a rated voltage range. Model analog signal.
  • 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 auxiliary model analog signal required to convert the assist model analog signal into the rated voltage range 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.
  • the annular groove rotating disk 1 and the annular groove fixing plate 40 of the sensor are sleeved outside the middle shaft 51 of the electric bicycle, and the annular groove fixing plate 40 and the central shaft 51 are externally
  • the sleeve 52 is fixedly connected, the annular groove rotating disk 1 of the sensor is fixedly connected with the middle shaft 51 of the electric bicycle, the annular groove rotating disk 1 is synchronously rotated with the middle shaft 51; the annular groove rotating disk 1 and the annular groove fixing plate 40 inner and outer phase sleeves are fitted into a rotational connection; the annular groove rotating disk 1 and the central axis 51 are the same center of rotation, and the signal output wire of the operational amplifier 28 in the sensor is connected to the signal input end of the motor controller 29 of the electric bicycle.
  • the permanent magnet block 2 on the annular groove rotating disk 1 rotates synchronously with the center shaft 51, and the permanent magnet block 2 rotates synchronously with the bicycle foot pedal 54, and the rotation of the permanent magnet block 2 rotates at the same angle as the foot pedal 54.
  • the Hall 3 on the annular groove fixing disk 40 senses the rotation angle and speed of the foot pedal 54 by sensing the rotation of the permanent magnet block 2.
  • the Hall 3 transmits the position and speed electric signals that sense the rotation of the permanent magnet block 2, that is, the position and speed electric signals representing the rotation of the footrest 54 to the electronic component assist model processor 21 on the circuit board 59, and the digital-to-analog converter 27.
  • the operational amplifier 28 performs signal processing.
  • the operational amplifier 28 is connected to the motor controller 29 of the electric bicycle, and realizes the purpose of controlling the electric bicycle by the electric signal of the sensor, that is, using the power assist model of the operational amplifier 28 to simulate the signal, or the standard assist model analog signal to control the electric bicycle, and obtaining the assist bicycle .
  • the assist bicycle of the present embodiment is a assist bicycle in which the human function is matched.
  • Embodiment 2 A high-density bicycle with a multi-magnetic block in a housing and a magnetic flux sensor
  • the annular groove in the hollow ring 41 rotates the disk 1 surface diameter of 10. 0 cm, in the ring groove rotating disk 1 set 40 permanent magnet blocks 2, 40 permanent magnet blocks 2
  • the diameters are 0.6 cm
  • the magnetic flux is 146-279 (B ⁇ H) max / KJ ⁇ m" 3 different selection values, and the magnetic flux adjacent to the permanent magnet block 2 is not equal.
  • Hall 3 and rotation Each permanent magnet block 2 of the state 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 rotation The structure of the disk 1, the permanent magnet block 2, and the Hall 3 is the same as that of the embodiment 1.
  • Embodiment 3 a bicycle having a specific circuit, and a multi-magnetic block in the casing, which distributes the magnetic flux sensor, as shown in FIGS. 1, 3, 5, and 6, as in Embodiment 1, the sensor includes a sensor element sequentially connected, and a power assist model is processed. 21, digital to analog converter 27 and operational amplifier 28; [1] Hall 3 in the sensing element selects UGN3075; the other elements 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 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 MCU 31 is connected to the digital-to-analog converter 27 of the 5 pin B1;
  • 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; Hall 3, single chip microcomputer 31, digital to analog converter connected in sequence in the sensing unit
  • the inner wall is fixed with a plurality of permanent magnet blocks 2, and the circuit board 59 is fixed on the inner wall of the annular groove fixing plate 40 of the hollow ring 41, the circuit board
  • the Hall 3 on 59 is set to sense the magnetic flux of the permanent magnet block 2, 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
  • the sensing function is integrally fixed to the electric bicycle, and the sensing function as a whole can 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 plate 40 of the hollow ring 41, so that the process for manufacturing the sensor is simplified.

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Abstract

A power-assist bicycle using sensor having multiple magnet blocks of unevenly distributed magnetic fluxes in a housing, related to electrical power-assisted bicycles that provide a power-assist signal with multipoint magnetic induction. The sensor comprises, sequentially connected, a sensing element, a power-assist model processor (21), a digital-to-analog converter (27), and an operational amplifier (28). The sensing element comprises permanent magnet blocks (2) and a Hall element (3) arranged in a cavity fitted together by a rotating disk (1) and a fixed disk (40). Arranged on the rotating disk are the multiple permanent magnet blocks that are opposite in adjacent magnetic polarities and different in magnetic fluxes. The Hall element on the fixed disk is arranged at a position in proximity to the permanent magnet blocks. The sensor is sleeved on the exterior of a central shaft (51) of the bicycle. The operational amplifier is connected to a motor controller. Advantages: the relative positions of the permanent magnet blocks and of the Hall element are fixed, the Hall element is allowed to acquire a rectangular wave signal, thereby facilitating the sensor to output via digital processing an artificially-set power-assist model, power-assist starting point, ending point, and reasonable power, thus allowing for optimal matching between human and machine and for electricity conservation.

Description

说 明 书  Description
用壳体内多磁块不均匀分布磁通量传感器的助力自行车 技术领域  Assisted bicycle with uneven distribution of magnetic flux sensor by multi-magnetic block in the casing
本发明属于助力自行车的技术领域,特别是涉及在一个转动部件上进行多点位磁感应 提供助力信号的电动助力自行车。  The invention belongs to the technical field of assisting bicycles, in particular to an electric assist bicycle which performs multi-point magnetic induction on a rotating component and provides a power assist signal.
背景技术 Background technique
野宝车料工业(昆山)有限公司申请的中国专利 201020295192.0《勾爪式力矩传感装 置》公开了一种助力自行车用传感装置, 传感装置包括磁性件和弹性件配合, 感受力矩的 传感装置。使用时间长后,弹性件的弹性系数变化就会导致传感信号与被控电机的控制效 果发生变化, 助力效果变得与人的助力需要不配合。而且用弹性件的设计结构复杂, 制造 成本高。  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. Moreover, the design of the elastic member is complicated and the manufacturing cost is high.
北京科技大学申请的中国专利 01201843.0《电动助力自行车自动检测装置》公开了一 种电动助力自行车自动检测装置,无接触检测蹬力、速度和转向,该装置在相对运动的内、 外轮盘上分别设磁片, 内轮盘上有弹簧, 内、外轮盘之间用弹簧复位, 用支架上的两个霍 尔测内、 外轮盘上相对运动的磁片产生的电信号表示蹬力、 速度和转向。  The Chinese patent 01201843.0 "Automatic assisted bicycle automatic detecting device" applied by Beijing University of Science and Technology discloses an automatic assisting bicycle automatic detecting device, which detects contact force, speed and steering without contact, and the device is respectively set on the inner and outer roulettes of relative motion. 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. .
缺点 (1 ) 用弹性件不耐久: 使用时间长后, 弹性件的弹性系数变化就会导致传感信 号与被控电机的控制效果发生变化, 助力效果变得与人的助力需要不配合, 结构复杂, 成 本高。  Disadvantages (1) 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.
缺点(2)各磁片组相同且磁极设置方式都相同, 而不能表示不同磁片组的各自位置, 不能表达不同位置特殊的助力需求: 从 01201843.0专利的图 3、 4、 5、 6和说明书第 2页 第 2段的记载说明, 每一个磁片组 (包括一个磁片 4、 一个磁片 5、 一个磁片 6) 的磁极 设置方式都相同, 即仅是在内轮的不同位置简单从复设置了完全相同的磁片组,不能表示 不同磁片组的各自位置, 不能表示特定位置的运动状态, 而人骑自行车时, 踏板和与踏板 相对应的各位置在运动状态,都有自己特殊的助力需求,但该专利这种各磁片组相同的结 构, 不能表达出踏板上各个不同位置特殊的助力需求。  Disadvantages (2) 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. When a person rides a bicycle, 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.
缺点 (3 ) 各位点信号无差异使人机不配合: 每一个磁片组都一样, 则每一个磁片组 不能表示该磁片组在内轮上的位置,霍尔所输出的信号不能表示脚踏板和其它磁片组的位 置, 即霍尔输出的信号不能表示不同脚踏位置对助力的需求,造成对助力的需求和提供助 力的时间不配合, 即人机配合不理想。  Disadvantages (3) There is no difference in the signal of each point to make the man-machine mismatch: Each disk group is the same, then each disk group cannot indicate the position of the disk group on the inner wheel, and the signal output by the Hall cannot be represented. The position of the pedals and other disk sets, that is, the signals output by the Halls cannot indicate the need for power assistance at different foot positions, resulting in a lack of coordination between the need for power assistance and the time for providing assistance, that is, the cooperation between the human and the machine is not ideal.
缺点 (4 ) 输出正弦波使磁片组边缘距离不能小于 4厘米, 一般以 5厘米为佳, 而使 可设磁片组数太少, 人机配合不理想: 各磁片组相同, 则霍尔输出的是正弦波作为控制信 号,作为控制信号正弦波必需有一定峰谷差值, 由于该专利的磁片组需要一定长度表示正 反向运动, 在直径为 20厘米的环形凹槽转动盘圆形轨迹上最多设 8个磁片组, 一般以 5 个为佳,霍尔才能有控制功能的正弦波信号。也就是说, 01201843.0专利的这种技术方案, 用于助力自行车, 磁片组数量受限止在 8个以内, 控制信号太少, 人机配合不理想。但如 果多于 8个磁片组, 在人踏车较快时, 霍尔输出的信号图形接近为一条水平线, 该信号没 有控制功能, 不能控制电动机, 使其特别需要助力时, 失去助力功能。 Disadvantages (4) Output sine wave so that the edge distance of the disk group can not be less than 4 cm, generally 5 cm is preferred, and the number of available magnetic disk groups is too small, the human-machine cooperation is not ideal: each disk group is the same, then Huo The output is a sine wave as a control letter No. There must be a certain peak-to-valley difference as a control signal sine wave. Since the patented magnetic disk group requires a certain length to indicate the forward and reverse movement, there are up to 8 circular tracks on the circular groove rotating disk with a diameter of 20 cm. For the disk group, it is generally better to use 5, and Hall can have a sine wave signal with control function. That is to say, 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. However, if there are more than 8 disk sets, when the person is treading faster, 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.
缺点 (5 )信号盲区达 45度角, 启动时需要助力的时候确得不到助力: 众所周知, 人 踩自行车脚踏板在顶点力矩最小, 从离开顶点 10-45度角是最需要助力的区域, 但该专利 各磁片组之间的夹角为 45度, 在脚踏板离开顶点 10-45度角区域没有一个磁片组, 也就 没有一个控制信号, 其结果是最需要助力的时候, 但助力自行车的电机确不能助力。  Disadvantages (5) The blind area of the signal reaches a 45-degree angle. When the power is required to start, it does not have the boost. It is well known that 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. However, 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 However, the motor that assists the bicycle does not help.
总之, 除用弹性件不耐久又结构复杂外, 因霍尔与磁片组的配合结构特点, 转盘大小 直径为 20厘米以内, 限止了磁片组数量为 8组, 磁片组数不能随意增加, 使人机配合不 理想, 而且启动时得不到助力, 助力需求与提供助力不匹配, 骑车人的舒适性差; 如强行 增加磁片组数量, 其传感信号又失去助力控制功能。  In short, in addition to the inflexible and complicated structure of the elastic member, due to the matching structure of the Hall and the magnetic disk group, 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.
王乃康申请的中国专利 03264387.X《时间型电动助力自行车传感器》 公开了不用弹 性件, 只用动、 定两个转盘, 动盘上面镶嵌两个永磁磁钢, 定盘上面镶嵌三个霍尔元件, 自行车踏板转一周, 每个霍尔产生两个脉冲, 则三个霍尔元件产生六个脉冲。分折可得三 个特点, 四个缺点如下:  Wang Naikang applied for the Chinese patent 03264387.X "Time-type electric power-assisted bicycle sensor" disclosed that without the elastic member, only two rotating and fixed turntables were set, two permanent magnets were set on the moving plate, and three Halls were set on the fixed plate. The component, the bicycle pedal rotates once a week, each Hall produces two pulses, and the three Hall elements produce six pulses. There are three characteristics of the fold, and the four shortcomings are as follows:
特点 (1 ) 为获得六个脉冲信号, 只能是各永磁磁钢相同磁极在一面: 每个霍尔要产 生两个脉冲, 则只能是两个永磁磁钢的相同磁极设在动盘的同一面, 即在动盘的某一面, 两个永磁磁钢都是北极或都是南极。假如在动盘的同一面, 一个永磁磁钢为北极, 另一个 为南极, 则踏板转一周, 每个霍尔就只能产生一个脉冲, 三个霍尔就只有三个脉冲, 这就 不合乎该专利说明书记载了。为了增加脉冲数, 提高控制效果, 只能是各永磁磁钢相同磁 极在一面。  Features (1) In order to obtain six pulse signals, only the same magnetic pole of each permanent magnet steel can be on one side: two pulses are generated for each Hall, then only the same magnetic pole of two permanent magnets can be set. The same side of the disk, that is, on one side of the moving plate, the two permanent magnets are all north or both. If on the same side of the moving plate, one permanent magnet is the north pole and the other is the south pole, then the pedal turns one week, each Hall can only produce one pulse, and the three Halls only have three pulses, which is not It is described in the patent specification. In order to increase the number of pulses and improve the control effect, only the same magnetic pole of each permanent magnet steel is on one side.
特点 (2) 永磁磁钢用于表示踏板固定位置, 三个霍尔表示踏板运动位置: 由于踏板 与动盘是同步转动,所以在与两个踏板对应的动盘上两个位置分别固定一个永磁磁钢,某 一个踏板转在什么位置, 则对应的永磁磁钢也转在什么位置; 但只有转在有霍尔的位置, 才能通过霍尔发出控制信号, 指挥助力自行车的电机产生需要的助力转动。  Features (2) 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.
特点 (3 ) 因为一个霍尔不能表示转一周中不同时段踏板运动的位置, 则就不能只用 一个霍尔: 踏板在转一周中的不同时段, 对助力需求是有很大差别的, 要体现这种助力需 求的变化,该专利用三个霍尔分别设在 180度角以内的三个位置,两个永磁磁钢分别设在 两个踏板位置,踏板转在有霍尔的位置,该霍尔就输出信号表示踏板到达了该霍元的位置。 但用多个霍尔又存在下面的缺点。 Features (3) Because a Hall cannot indicate the position of pedaling in different periods of the week, you can't use only one Hall: The pedals are very different in the different time periods of the week. This change in boosting demand, the patent uses three Halls set at three positions within a 180 degree angle, two permanent magnets are placed in In the two pedal positions, the pedal is turned to the position with the Hall, and the Hall outputs a signal indicating that the pedal has reached the position of the Hawk. However, the use of multiple Halls has the following disadvantages.
作为助力自行车传感器的这些特点会有三个缺点:  These features, as a booster bicycle sensor, have three drawbacks:
缺点 (1 ) 用两个没有差异性的永磁磁钢分别表示两个踏板的固定位置, 就只能用多 个霍尔来表示踏板的转动位置:两个永磁磁钢没有差异性,优点是可以不分左右脚的分别 表示两个踏板的固定位置, 使其左右脚发生助力需求, 可产生相同的电机助力效果; 但缺 点是永磁磁钢本身就不能表示踏板的转动位置,而只能用多个霍尔设在不同的转角位置来 表示踏板的转动位置, 所以不能只用一个霍尔, 而必需用多个霍尔。  Disadvantages (1) Two permanent magnets with no difference are used to indicate the fixed position of the two pedals. Only the Hall can be used to indicate the rotational position of the pedal: there is no difference between the two permanent magnets. It is possible to indicate the fixed positions of the two pedals regardless of the left and right feet, so that the left and right feet can generate the same power assist effect; but the disadvantage is that the permanent magnet steel itself cannot indicate the rotational position of the pedal, but only It is possible to use multiple Halls at different corner positions to indicate the rotational position of the pedal, so it is not possible to use only one Hall, but multiple Halls are necessary.
缺点 (2) 不能只用一个霍尔, 而三个霍尔必然造成三个控制信号有原始分段误差, 使助力需求模型失真, 自然产生助力输出与助力需求不一致:助力自行车不论是一个或两 个电机,其控制电机的传感信号只能用一个传感信号输入电机控制器才能达到控制电机的 目的;而该专利用三个霍尔控制电机,则必需把三个霍尔的三个控制信号合并为一个合并 控制信号后才能输入电机控制器。三个霍尔的传感参数不可能一样,特别是由于环境温度 变化、使用时间长后,三个霍尔的传感参数可能差异很大,其结果造成相同的助力需求时, 不同霍尔的输出的是不同电压,导致电机产生不同的助力输出,助力输出与助力需求不一 致; 同理相同的助力需求时, 不同霍尔的输出的又可能是相同电压, 导致电机产生同一种 助力输出, 也产生助力输出与助力需求不一致的问题。  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. For a motor, 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. When the same boosting demand is used, 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.
缺点 (3 ) 合并控制信号易产生信号漂移, 使合并控制信号与电机控制器不匹配, 助 力需求模型失真:由于环境温度变化、使用时间长后,三个霍尔的传感参数可能差异很大, 三个霍尔的三个控制信号连接点必然变化,则相同的助力需求产生的合并控制信号就会产 生分段性的信号漂移, 合并控制信号作为一整体产生信号失真, 即助力需求模型失真, 造 成电机控制器选用三个控制信号的任何一个作为基准都会产生助力输出与助力需求不一 致的问题。  Disadvantages (3) 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.
缺点 (4) 传感位点不能随意增加, 传感位点太少, 电机运行就不平稳, 使骑车的人 感觉很不舒服: 由于有缺点 (1 )和缺点 (2)都最因为霍尔数量大于一个造成的, 很明显 霍尔数量越量越多, 缺点 (1 )和缺点 (2)表现越严重。 所以, 该专利提供的助力自行车 只能是使骑车的人感觉舒适性很不好的助力自行车。  Disadvantages (4) 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.
缺点 (5 )信号盲区达 42度角, 启动时需要助力的时候确得不到助力: 众所周知, 人 踩自行车脚踏板在顶点力矩最小, 从离开顶点 10-45度角是最需要助力的区域, 但该专利 各霍尔之间的夹角为 42.5-43.5度, 在脚踏板离开顶点 10-42度角区域没有一个霍尔, 也 就没有一个控制信号, 其结果是最需要助力的时候, 但助力自行车的电机确不能助力。 总之,该专利是用多个霍尔控制助力模式的技术方案, 因为只能用多个霍尔来表示踏 板的转动位置,多个霍尔的多个控制信号必然有原始误差,其合并控制信号又易产生信号 漂移,都可造成助力需求模型失真,即不同时间的相同助力需求,但获得不同的助力效果; 霍尔数量越量越多, 助力需求模型失真越严重, 限止了霍尔了数量, 霍尔少数量了又产生 电机运行就不平稳, 使骑车的人感觉很不舒服, 而且启动时得不到助力。使其要助力需求 模型不失真, 和要电机运行平稳这两个问题上总是顾此失彼, 不可兼得。 Disadvantages (5) The blind area of the signal reaches a 42-degree angle. When 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. In short, 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.
发明内容 Summary of the invention
本发明的目的是提供只用一个霍尔和环形凹槽转动盘上各个永磁块磁通量变化获得 自行车踏板的速度和位置信号、并对信号进行数字化处理成为有最佳助力模型信号传感器 的助力自行车; 是一种在霍尔可感应区域内, 能尽量增加永磁块数量, 最大限度利用自行 车踏板位移信息,传感器输出信息多又精确定位,传感器用一个组合件固定霍尔和多个永 磁块相对位置的助力自行车;在使用助力自行车上,骑车人的助力需求与电机提供的助力 匹配良好, 电机运行平稳的助力自行车。  SUMMARY OF THE INVENTION It is an object of the present invention to provide a speed-and-position signal for a bicycle pedal by using only one Hall and an annular groove to rotate the magnetic flux of each permanent magnet block on the disk, and digitally processing the signal to become a power-assisted bicycle having an optimal power model signal sensor. In the Hall-sensing area, it is possible to increase the number of permanent magnet blocks as much as possible, to maximize the use of bicycle pedal displacement information, and to accurately position the sensor output information. The sensor uses one assembly to fix the Hall and multiple permanent magnet blocks. The relative position of the assisted bicycle; on the use of the assisted bicycle, the assisting demand of the rider is well matched with the assist provided by the motor, and the motor runs smoothly to assist the bicycle.
本发明的构思是:在一个霍尔可感受范围内,一个环形凹槽转动盘上用多个永磁块向 霍尔的那一面进行南、 北磁极性交替变化, 使其一个霍尔可感受全部永磁块的运动信号。 多个永磁块的变化方式主要是磁极性变化、 磁通量变化, 目的使霍尔可获得有特定位置、 位置更精确、控制功能更强、数量更多的永磁块运动信号。多个永磁块磁极性用南极北极 交替变化, 使霍尔产生的信号为矩形波, 使信号的控制功能更强、数量更多; 多个永磁块 磁通量变化使霍尔产生的信号能表达永磁块的位置更精确,从而可以表达环形凹槽转动盘 特定位置的运动状态。对于助力自行车,表达脚踏板的特定位置是在什么运动状态非常重 要, 因为脚踏板的运动状态直接表示了人对车的助力需求状态。  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. For a booster bicycle, it is important to express the specific position of the foot pedal in what state of motion, because the motion state of the foot pedal directly indicates the state of the person's assist demand for the vehicle.
用一个机械结构的组合件固定传感元件霍尔和多个永磁块的相对位置,使其传感信号 稳定可靠。  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.
把霍尔输出的矩形波信号变为数字信号,方使对霍尔的数字信号进行数字化处理,在 数字化处理过程中可加入使人机能最佳配合的助力数学模型,助力数学模型是可按人机配 合进行随意调整的。克服了现有技术霍尔输出的正弦波信号难以进行数字化处理,只能进 行模拟化信号处理而不能加入可随意调整的助力模型、克服了只能提取受速度信号条件限 止的助力模型、 克服了使人机不能最佳配合的问题。  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.
本发明的结构是:  The structure of the invention is:
用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 包括电动自行车和传感器, 电动自行车有中轴 51, 中轴 51中间段套有套管 52, 中轴 51与套管 52转动连接; 中轴 51上固定有链盘 53, 中轴 51两端分别固定有脚踏板 54; 电动自行车上电池 55连接电机 控制器 29, 电机控制器 29连接车轮上的电机 30; 其特征在于: A power-assisted bicycle with a magnetic flux sensor distributed in a multi-magnetic block in the casing, including an electric bicycle and a sensor, the electric bicycle has a middle shaft 51, and the middle portion 51 is sleeved with a sleeve 52, and the central shaft 51 is rotatably connected with the sleeve 52; Central axis The chain plate 53 is fixed on the 51, and the foot pedal 54 is fixed on both ends of the central shaft 51; the electric battery 55 is connected to the motor controller 29, and the motor controller 29 is connected to the motor 30 on the wheel;
传感器的结构和部件的连接关系如下:  The structure of the sensor and the connection relationship of the components are as follows:
包括依次连接的传感元件、 助力模型处理器 21、 数模转换器 27和运算放大器 28;  Including a sensing element connected in sequence, a boost model processor 21, a digital to analog converter 27 and an operational amplifier 28;
[ 1 ] 传感元件是把环形凹槽转动盘 1的转动运动变为矩形波信号输出的元件;  [1] The sensing element is an element that changes the rotational motion of the annular groove rotating disk 1 into a rectangular wave signal output;
传感元件包括一块环形凹槽转动盘 1、环形凹槽固定盘 40、一个霍尔 3和多枚永磁块 2, 环形凹槽转动盘 1和环形凹槽固定盘 40两者的凹面相对, 环形凹槽固定盘 40嵌合在 环形凹槽转动盘 1的环形凹槽之中,成两个盘能相对转动的嵌合内空外壳,两个盘的凹面 夹成一个空心环 41 ; 在空心环 41位置的环形凹槽转动盘 1上固定设置有多枚永磁块 2, 该多枚永磁块 2均勾地呈圆形轨迹分布,即每枚永磁块 2到圆形轨迹线 5所在圆中心的距 离相同、 相邻永磁块 2之间的距离相同; 相邻永磁块 2的磁极性相反, 环形凹槽转动盘 1 上全部永磁块 2的磁极性分布方式是 N极、 S极、 N极、 S极、 N极、 S极……; 至少 有两枚永磁块 2的磁通量不相同;  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, and the annular groove rotating disk 1 and the annular groove fixing disk 40 are concavely opposed to each other, The annular groove fixing plate 40 is fitted in the annular groove of the annular groove rotating disk 1, and the two disks can be relatively rotated to fit the hollow inner casing, and the concave surfaces of the two disks are sandwiched into a hollow ring 41; The annular groove rotating disk 1 at the position of the ring 41 is fixedly provided with a plurality of permanent magnet blocks 2, and the plurality of permanent magnet blocks 2 are distributed in a circular trajectory, that is, each permanent magnet block 2 to a circular trajectory line 5 The distance between the centers of the circles is the same, the distance between the adjacent permanent magnet blocks 2 is the same; the magnetic polarity of the adjacent permanent magnet blocks 2 is opposite, and the magnetic polarity distribution pattern of all the permanent magnet blocks 2 on the rotating disk 1 of the annular groove is the N pole. , S pole, N pole, S pole, N pole, S pole ...; at least two permanent magnet blocks 2 have different magnetic fluxes;
在空心环 41的环形凹槽固定盘 40上固定设置有一个霍尔 3,霍尔 3设在接近永磁块 2并能感受每个永磁块 2磁通量的位置, 霍尔 3与永磁块 2之间有间距; 霍尔 3是对相反 磁极性产生矩形波输出信号的霍尔;  A Hall 3 is fixedly disposed on the annular groove fixing plate 40 of the hollow ring 41. The Hall 3 is disposed near the permanent magnet block 2 and can sense the magnetic flux of each permanent magnet block 2, and the Hall 3 and the permanent magnet block There is a gap between 2; Hall 3 is a Hall that produces a rectangular wave output signal to the opposite magnetic polarity;
[2]助力模型处理器 21是把环形凹槽转动盘 1转动的数字信号变为助力模型数字信号的 信号形式转换器;  [2] 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;
助力模型处理器 21包括模数转换和波峰识别器 22、助力起点选择器 23、磁块转速计 算器 24、 助力模型存储器 25和助力模型计算器 26;  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;
模数转换和波峰识别器 22与传感元件连接,模数转换和波峰识别器 22把传感元件中 霍尔 3输入的矩形波信号进行识别各个矩形波的波峰,将各个矩形波信号变为不同的数字 信号, 对每个矩形波进行标注, 模数转换和波峰识别器 22输出标注有磁块位置秩序的磁 块运动数字信号;  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;
模数转换和波峰识别器 22分别与助力起点选择器 23和磁块转速计算器 24连接, 助 力起点选择器 23与磁块转速计算器 24连接; 磁块转速计算器 24用模数转换和波峰识别 器 22输入的标注有磁块位置秩序的磁块运动数字信号计算出环形凹槽转动盘 1的转速, 并把环形凹槽转动盘 1的转速数字信号传给助力起点选择器 23,助力起点选择器 23用标 注有磁块位置秩序的磁块运动数字信号,和环形凹槽转动盘 1的转速数字信号这两个信号 确定在某种转速条件下的助力起点对应的某一个矩形波, 即确定助力起点磁块;  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;
助力起点选择器 23和磁块转速计算器 24分别都与助力模型计算器 26连接, 助力模 型存储器 25也与助力模型计算器 26连接;助力模型计算器 26用助力起点选择器 23的助 力起点磁块, 和用磁块转速计算器 24的环形凹槽转动盘 1转速这两个条件选择助力模型 存储器 25中的某一种助力模型函数, 并将助力起点磁块和环形凹槽转动盘 1转速这两个 条件代入助力模型函数,计算出适合这两个条件的助力模型数字信号, 即助力模型计算器 26输出助力模型数字信号; The assist start point selector 23 and the magnetic block rotational speed calculator 24 are respectively connected to the assist model calculator 26, and the assist mode The type memory 25 is also connected to the assist model calculator 26; the boost model calculator 26 is selected by the assist starting point magnet block of the assist starting point selector 23, and the rotational speed of the disc 1 by the annular groove of the magnetic block rotational speed calculator 24. Assisting one of the assist model functions in the model memory 25, and substituting the two conditions of the assist starting magnetic block and the annular groove rotating disk 1 into the assisting model function, and calculating the assisting model digital signal suitable for the two conditions, that is, The assist model calculator 26 outputs the boost model digital signal;
[3 ] 数模转换器 27是把助力模型数字信号转换成助力模型的模拟信号;  [3] The digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model;
助力模型计算器 26与数模转换器 27连接,数模转换器 27把助力模型计算器 26的助 力模型数字信号转换成助力模型模拟信号;  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;
[4] 运算放大器 28是把数模转换器 27的助力模型模拟信号转换成额定电压范围的助力 模型模拟信号。  [4] 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.
传感器与电动自行车的连接关系是: 传感器的环形凹槽转动盘 1 和环形凹槽固定盘 40套在电动自行车的中轴 51外, 并且环形凹槽固定盘 40与中轴 51外的套管 52固定连 接, 传感器的环形凹槽转动盘 1与电动自行车的中轴 51固定连接, 环形凹槽转动盘 1伴 随中轴 51同步转动;环形凹槽转动盘 1与环形凹槽固定盘 40内外相套的嵌合成转动连接; 环形凹槽转动盘 1和中轴 51两者为相同的转动中心,传感器中运算放大器 28的信号输出 导线与电动自行车的电机控制器 29的信号输入端连接。  The connection relationship between the sensor and the electric bicycle is: the annular groove rotating disk 1 of the sensor and the annular groove fixing plate 40 are sleeved outside the middle shaft 51 of the electric bicycle, and the annular groove fixing plate 40 and the sleeve 52 outside the middle shaft 51 The fixed connection, the annular groove rotating disk 1 of the sensor is fixedly connected with the central shaft 51 of the electric bicycle, the annular groove rotating disk 1 is synchronously rotated with the central shaft 51; the annular groove rotating disk 1 and the annular groove fixing plate 40 are arranged inside and outside. The fitting is a rotational connection; both the annular groove rotating disk 1 and the central axis 51 are the same center of rotation, and the signal output wire of the operational amplifier 28 in the sensor is connected to the signal input terminal of the motor controller 29 of the electric bicycle.
一、对传感器工作原理的说明: 以工作原理把传感器分为信号获取和信号处理, 以便说明 传感器的各个部件的结构关系和作用。信号获取由传感元件的环形凹槽转动盘 1、环形凹 槽固定盘 40、 永磁块 2和霍尔 3进行合理设置而执行获取信号功能; 信号处理由助力模 型处理器 21、 数模转换器 27和运算放大器 28依次连接把霍尔 3输出的信号处理成电动 自行车的电机控制器 29能使用的助力模型模拟信号。 First, the description of the working principle of the sensor: According to the working principle, the sensor is divided into signal acquisition and signal processing, in order to explain the structural relationship and function of each component of the sensor. The signal acquisition is performed by the annular groove rotating disk 1, the annular groove fixing disk 40, the permanent magnetic block 2 and the Hall 3 of the sensing element to perform a function of acquiring signals; the signal processing is performed by the assist model processor 21, digital-to-analog conversion The comparator 27 and the operational amplifier 28 are sequentially connected to process the signal output from the Hall 3 into an assist model analog signal that can be used by the motor controller 29 of the electric bicycle.
[一] 对传感元件的说明:  [1] Description of the sensing element:
环形凹槽转动盘 1与环形凹槽固定盘 40即嵌合, 又能相对转动, 保证了在环形凹槽 转动盘 1转动状态,霍尔 3与全部永磁块 2的感应位置不变化,使霍尔 3的输出信号只与 全部永磁块 2的转动有关,而与环形凹槽转动盘 1与环形凹槽固定盘 40以下的物件无关; 如果环形凹槽转动盘 1与环形凹槽固定盘 40用金属材料, 又可有屏蔽作用, 所以, 用环 形凹槽转动盘 1与环形凹槽固定盘 40将霍尔 3与全部永磁块 2置于空心环 41进行感应, 提高了霍尔 3信号的可靠性、 真实性。  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.
当把环形凹槽固定盘 40固定在某一物件上, 转动环形凹槽转动盘 1, 环形凹槽转动 盘 1上的各个永磁块 2扫过环形凹槽固定盘 40上的霍尔 3时, 每个永磁块 2都能使霍尔 3产生电信号。 由于相邻永磁块 2的磁极性相反, 即全部永磁块 2的磁极性南、 北交替的 面对霍尔 3, 则霍尔 3产生电信号为矩形波信号, 矩形波信号方便进行数字化处理信号, 用于实现数字化控制。现有技术是全部永磁块 2的用同一个磁极性面向霍尔 3, 霍尔 3就 只能产生正弦波信号, 所以只能用于模拟控制; 一但霍尔 3的感应参数变化, 模拟控制就 可能失真。 而本发明用矩形波信号实现数字化控制, 不会产生控制失真的问题。 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 alternate south and north. Facing the Hall 3, the Hall 3 generates an electric signal as a rectangular wave signal, and the rectangular wave signal is convenient for digitizing the signal for digital control. In the prior art, all of the permanent magnet blocks 2 are facing the Hall 3 with the same magnetic polarity, and 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. However, the present invention realizes digital control by using a rectangular wave signal without causing a problem of controlling distortion.
环形凹槽转动盘 1可以是塑料板、 高强度绝板、铜板、铝板等不易变形的材料板。使 用传感元件时,环形凹槽转动盘 1要转动,转动的中心就是多个永磁块 2成圆环形分布所 在圆的中心。  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. When the sensing element is used, 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.
多个永磁块 2成圆环形分布的目的在于可以只用一个霍尔 3感受环形凹槽转动盘上全 部永磁块 2的运动状态, 即感受环形凹槽转动盘上全部永磁块 2的运动位置和速度, 以及 速度的变化,或称加速度,这一个霍尔 3就能把永磁块 2的运动状态用一个连续的电信号 来表达,又因为全部永磁块 2是分别固定在环形凹槽转动盘即环形凹槽转动盘 1上的,则 霍尔 3产生的连续电信号就能表达环形凹槽转动盘的运动状态。如果把这个连续电信号用 于控制其它物体, 这个连续电信号就是控制信号。如果用于控制助力自行车的电机, 还需 要用单片机或其它电子元件作为传感信号处理器, 把控制信号中的位置、速度、加速度要 索转换成需要助力多少的助力信号, 换算的函数就是助力需求模型, 或称助力模型。  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. The position and speed of the movement, as well as the change in speed, or acceleration, 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. 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. A demand model, or a help model.
多个永磁块 2磁通量不相同的意义是:使霍尔 3产生的电信号中不是完全一样的脉冲 信号,而是峰谷差值不同的脉冲信号,用有区别的脉冲信号来区别不同永磁块 2的不同位 置,从而可以获得不同位置永磁块 2的运动状态。达到可精确表达环形凹槽转动盘某个位 置, 或每个有永磁块 2的运动状态。如用于助力自行车, 可精确表达脚踏在不同位置对助 力的需求, 使助力需求的表达更精确, 则车与人的配合就更一致。  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 groove of the annular groove, or each of the movement states of the permanent magnet block 2. For example, when it is 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.
多个永磁块 2磁通量不相同也就是多个永磁块 2的磁通量是有变化的,其变化的范围 应是位置不变的同一个霍尔 3能感受的磁通量范围,也就是说,多个永磁块 2磁通量的最 高值和最低值应在霍尔 3能感受的磁通量范围内。  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.
霍尔 3设在接近永磁块 2并能感受永磁块 2磁通量的位置,目的在于用霍尔 3感受永 磁块 2的运动状态, 即运动位置、 速度、 加速度。  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.
相邻永磁块 2的磁极性相反是很重要的技术特征,全部永磁块 2的磁极性分布方式是 N极、 S极、 N极、 S极、 N极、 S极……, 使霍尔 3输出高、 低相间的矩形波信号, 作为大小受限止的环形凹槽转动盘,转动一周要获得尽量多的精确变化信号, 当然应是选 用矩形波。 因为矩形波信号的峰谷值变化的时间短, 可在一定的时间内, 产生尽量多的有 控制意义的信号。相邻永磁块 2的磁极性相反的结构产生矩形波,而相邻永磁块 2的磁极 性相同的结构产生正弦波,特别是用于助力自行车时,作为传感部件的环形凹槽转动盘一 般限止在直径为 10-15厘米, 在这种限范围要获得有控制功能的信号, 转动一周, 产生矩 形波比产生正弦波可提供的脉冲个数多 7-9倍。 自然, 相邻永磁块 2的磁极性相反的结构 对助力自行车的控制效果更的, 人与车配合更好, 乘骑人感觉更舒服。 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. Of course, rectangular wave should be used. Because the peak-to-valley value of the rectangular wave signal changes for a short period of time, as many controlled 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. Panyi Generally, the diameter is 10-15 cm. In this range, a signal with control function is obtained, and one rotation is made, and the rectangular wave is generated 7-9 times more than the number of pulses that the sine wave can provide. Naturally, the structure with the opposite magnetic polarity of the adjacent permanent magnet block 2 has a better control effect on the assisting bicycle, and the person and the vehicle cooperate better, and the rider feels more comfortable.
[二]助力模型处理器 21的说明:助力模型处理器 21是把环形凹槽转动盘 1转动的数字 信号变为助力模型数字信号的信号形式转换器;  [II] Description of the assist model processor 21: 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;
助力模型处理器 21包括模数转换和波峰识别器 22、助力起点选择器 23、磁块转速计 算器 24、助力模型存储器 25和助力模型计算器 26; 这些部件对信号的处理思路是: 把传 感元件中霍尔 3的矩形波信号分解出表示磁块 2位置的位置数字信号,和表示环形凹槽转 动盘 1转速的速度数字信号, 由于位置和速度都是数字信号,就可以对位置和速度用助力 数学模型处理, 可以按人的最佳感觉进行设计助力数学模型, 使其助力模型处理器 21输 出的助力模型数字信号即具有最佳助力数学模型, 又有该助力数学模型的启动点和终止 点,因为有磁块 2的位置数字信号,所以启动点和终止点准确到与人的助力需求完全同步。 解决了现有技术没有磁块 2位置信号而导致人的助力需求与助力模型不匹配,和助力模型 的运行延迟于助力需求的问题, 解决了现有技术要力不给力, 要大力只给小力, 要小力又 给大力, 不要力又给力等人机不配合的问题。 助力模型处理器 21中各部件的连接关系和 功能如下:  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. Since 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 and functions of the components in the power model processor 21 are as follows:
模数转换和波峰识别器 22与传感元件连接,模数转换和波峰识别器 22把传感元件中 霍尔 3输入的矩形波信号进行识别各个矩形波的波峰,将各个矩形波信号变为不同的数字 信号, 对每个矩形波进行标注, 模数转换和波峰识别器 22输出标注有磁块位置秩序的矩 形波信号。这样, 把波形有峰值区别的矩形波信号变为用数据标注的矩形波信号, 方便在 后面的数字化处理过程中, 把矩形波峰值变为矩形波位置数据进行运算处理。所以, 模数 转换和波峰识别器 22是把矩形波峰值表示磁块位置的信号, 变为用数据标注磁块位置的 数字信号的处理器。这是本发明区别于现有助力自行车的重要发明点,有了用数据标注磁 块位置的数字信号,本发明就能在循环圆周运动的环形凹槽转动盘 1上找到某一个或每个 磁块位置, 为电机 30启动产生助力、增加助力、减少助力、停止助力等电机 30工作找到 了起点和终点, 使人的助力需求与电机 30助力行为能相匹配, 避免了现有助力自行车难 以实现人机配合, 出现需要助力时电机 30不转动,不需要助力时电机 30还保持运动不能 停下来, 甚至造成冲撞事故的问题。  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. Therefore, 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 block position, for the motor 30 to start to generate power, increase the power, reduce the power, stop the power and other motor 30 work to find the starting point and the end point, so that the power demand can be matched with the motor 30 assist behavior, avoiding the existing power bicycle is difficult to achieve When the man-machine cooperates, 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.
模数转换和波峰识别器 22分别与助力起点选择器 23和磁块转速计算器 24连接, 助 力起点选择器 23与磁块转速计算器 24连接; 磁块转速计算器 24用模数转换和波峰识别 器 22输入的标注有磁块位置秩序的磁块运动数字信号计算出环形凹槽转动盘 1的转速, 并把环形凹槽转动盘 1的转速数字信号传给助力起点选择器 23,助力起点选择器 23用标 注有磁块位置秩序的磁块运动数字信号,和环形凹槽转动盘 1的转速数字信号这两个信号 确定在某种转速条件下的助力起点对应的某一个矩形波, 即确定助力起点磁块。 由于, 确 定的助力起点磁块是有数据标注的矩形波,则助力起点磁块有唯一对应的磁块 2位置,这 样, 助力起点选择器 23完成了找出助力起始点的磁块 2位置, 也就可以确定某个磁块 2 在什么位置时,启动或结束电机进行某种助力模型运动。这就达到人控制环形凹槽转动盘 1的特定磁块 2同步运动, 特定磁块 2控制电机 30进行特定的同步转动, 实现人同步控 制电机的目的,不会出现控制的起点和终点不准确,不会出现控制的起点和终点延迟的问 题。但现有助力自行车在启止助力时, 都找不到与人同步的启止位置, 所以都会产生控制 的起点和终点延迟的问题。 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 by 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 transmitting the digital signal of the rotational speed of the annular groove rotating disk 1 to the assisting start point selector 23, the boosting starting point selector 23 uses the magnetic block moving digital signal marked with the position of the magnetic block, and the rotational speed digital signal of the circular groove rotating disk 1. These two signals 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. 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.
助力起点选择器 23和磁块转速计算器 24分别都与助力模型计算器 26连接, 助力模 型存储器 25也与助力模型计算器 26连接;助力模型计算器 26用助力起点选择器 23的助 力起点磁块, 和用磁块转速计算器 24的环形凹槽转动盘 1转速这两个条件选择助力模型 存储器 25中的某一种助力模型函数, 并将助力起点磁块和环形凹槽转动盘 1转速这两个 条件代入助力模型函数,计算出适合这两个条件的助力模型数字信号, 即助力模型计算器 26就能输出助力模型数字信号。  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 can output the assist model digital signal.
[三]对数模转换器 27的说明:数模转换器 27是把助力模型数字信号转换成助力模型的 模拟信号。  [3] Description of the digital-to-analog converter 27: The digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model.
助力模型计算器 26与数模转换器 27连接,数模转换器 27把助力模型计算器 26的助 力模型数字信号转换成助力模型模拟信号。 以便向只能处理模拟信号的电机控制器 29输 出助力模型的模拟信号。  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.
[四] 对运算放大器 28的说明: 运算放大器 28是把数模转换器 27的助力模型模拟信号 转换成额定电压范围的助力模型模拟信号。  [4] Explanation of the operational amplifier 28: 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.
数模转换器 27与运算放大器 28连接, 数模转换器 27的助力模型模拟信号虽然解决 了助力模型问题, 但助力模型信号的电压还不能满足电机控制器 29的需要, 所以还要用 运算放大器 28把助力模型模拟信号转换成额定电压范围需要的助力模型模拟信号, 才能 传输给电机控制器 29。  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.
二、 对传感器与电动自行车连接组成助力自行车的说明: Second, the description of the connection between the sensor and the electric bicycle to form a power-assisted bicycle:
为说明实物安装,从实物方面传感器分为机械部件和传感部件, 以说明传感器的各个 实物与电动自行车各有关实物的结构关系。机械部件由环形凹槽转动盘 1和环形凹槽固定 盘 40相卡接相嵌成转动连接关系, 组成有环形内空的壳体结构。 壳体环形内空中装有传 感部件, 传感部件的多个永磁块 2固定在壳体环形内空中的环形凹槽转动盘 1的内表面, 永磁块 2与环形凹槽转动盘 1同步转动, 使多个永磁块 2与自行车脚踏板 54同步转动, 达到用多个永磁块 2表示骑自行车人对助力需求的机械动作的目的。 传感部件的霍尔 3、 助力模型处理器 21、 数模转换器 27和运算放大器 28固定在壳体环形内空中环形凹槽固 定盘 40的内表面, 环形凹槽固定盘 40与自行车车架的套管 52固定, 使环形凹槽固定盘 40不随环形凹槽转动盘 1转动, 固定在环形凹槽固定盘 40上的传感部件霍尔 3、 助力模 型处理器 21、数模转换器 27和运算放大器 28也不随环形凹槽转动盘 1转动,使其霍尔 3 能用一个固定位置感受全部永磁块 2的转动位置,从而可以把骑自行车人对助力需求的机 械动作全部变为电信号, 再通过传感部件助力模型处理器 21、数模转换器 27和运算放大 器 28, 把霍尔 3的助力需求电信号变为人机匹配的助力模型电信号, 运算放大器 28把人 机匹配的助力模型电信号传给电机控制器 29, 电机控制器 29控制电机 30按人机匹配的 方式转动, 最终实现助力自行车按人的最佳需求方式运动, 即实现人机匹配的效果。 In order to explain the physical installation, the sensor is divided into a mechanical component and a sensing component from the physical aspect to illustrate the structural relationship between each physical object of the sensor and the physical object of the electric bicycle. The mechanical component is in a rotationally coupled relationship by the annular groove rotating disk 1 and the annular groove fixing disk 40, and is formed into a ring-shaped inner casing structure. The shell is enclosed in the air a plurality of permanent magnet blocks 2 of the sensing member are fixed on the inner surface of the annular groove rotating disk 1 in the annular inner space of the casing, and the permanent magnet block 2 rotates synchronously with the annular groove rotating disk 1 to make a plurality of permanent magnets The block 2 rotates in synchronism with the bicycle footrest 54 to achieve the purpose of using the plurality of permanent magnet blocks 2 to represent the cyclist's mechanical action for the assisting demand. The Hall 3 of the sensing member, the assist model processor 21, the digital-to-analog converter 27 and the operational amplifier 28 are fixed to the inner surface of the annular annular groove fixing disk 40 in the annular inner casing of the casing, the annular groove fixing plate 40 and the bicycle frame The sleeve 52 is fixed so that the annular groove fixing plate 40 does not rotate with the annular groove rotating disk 1, and the sensing member Hall 3, the assist model processor 21, and the digital-to-analog converter 27 are fixed on the annular groove fixing plate 40. And the operational amplifier 28 does not rotate with the annular groove rotating disk 1, so that the Hall 3 can sense the rotational position of all the permanent magnet blocks 2 with a fixed position, so that the cyclist's mechanical action for the power demand can be turned into electricity. The signal, through the sensing component, assists the model processor 21, the digital-to-analog converter 27, and the operational amplifier 28, and changes the power demand signal of the Hall 3 into a power-assisted model electrical signal that is matched by the human-machine, and the operational amplifier 28 matches the human-machine. The power signal of the power-assisted model is transmitted to the motor controller 29, and the motor controller 29 controls the motor 30 to rotate in a matching manner of the human-machine, and finally realizes that the power-assisted bicycle moves according to the best demand of the person, that is, Human-computer matching results.
本发明传感器中各信号处理部件输出的信号为:  The signals output by the signal processing components in the sensor of the present invention are:
霍尔 3输出矩形波信号; Hall 3 outputs a rectangular wave signal;
助力模型处理器 21输出助力模型数字信号; The assist model processor 21 outputs the assist model digital signal;
模数转换和波峰识别器 22输出标注有磁块位置秩序的磁块运动数字信号; 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;
助力起点选择器 23输出确定的助力起点磁块的起点位置信号; The assist starting point selector 23 outputs a determined start position signal of the assist starting point magnet block;
磁块转速计算器 24计算并输出环形凹槽转动盘 1的转速数字信号; The magnetic block rotational speed calculator 24 calculates and outputs a digital signal of the rotational speed of the annular groove rotating disk 1;
助力模型存储器 25存有多种助力模型函数备用,输出已选定的助力模型函数的数字信号; 助力模型计算器 26计算并输出将用于控制功能的助力模型数字信号; 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;
数模转换器 27输出把助力模型数字信号转换成的助力模型模拟信号; The digital-to-analog converter 27 outputs an assist model analog signal that converts the power model digital signal into a power model;
运算放大器 28输出把助力模型模拟信号转换成额定电压范围的助力模型模拟信号; The operational amplifier 28 outputs an assist model analog signal that converts the assist model analog signal into a rated voltage range;
热敏电阻 R6保证运算放大器 28输出的是额定电压范围的助力模型模拟信号, 即标 准助力模型模拟信号。  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.
为解决助力模型模拟信号漂移问题设有热敏电阻 R6, 热敏电阻 R6连接在运算放大 器 28的输入端和输出端之间。  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.
霍尔 3、 数模转换器 27和运算放大器 28都是半导体器件, 又有处理模拟信号功能, 很易随温度变化而使信号参数产生漂移, 特别是夏天和冬天, 助力自行车又都在室外,温 度变化产生信号参数漂移的效果明显, 所以, 最好对运算放大器 28输出的信号进行信号 漂移修正,获得不受温度变化影响的标准助力模型模拟信号,将标准助力模型模拟信号通 过电机控制器 29控制电机 30运行,骑助力自行车的人就不会感到夏天和冬天助力效果不 同的问题。 Hall 3, digital-to-analog converter 27 and operational amplifier 28 are both semiconductor devices and have the function of processing analog signals. It is easy to drift signal parameters with temperature changes, especially in summer and winter, and the bicycles are all outdoors. The effect of temperature variation on the signal parameter drift is obvious. Therefore, it is better to perform signal drift correction on the signal output from the operational amplifier 28 to obtain a standard power assist model analog signal that is not affected by temperature changes, and pass the standard assist model analog signal to the motor controller 29 Control motor 30 to run, people riding bicycles will not feel the summer and winter power effect is not The same problem.
助力模型处理器 21是单片机 31,单片机 31上连接有时钟电路 32。用单片机 31完成 模数转换和波峰识别器 22、助力起点选择器 23、磁块转速计算器 24、助力模型存储器 25 和助力模型计算器 26的功能。时钟电路 32的时钟信号是用于对霍尔 3输入的矩形波信号 进行区分的作用, 优选每个时钟信号的长度为 0.001秒。  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.
传感器的机械部件与传感部件结构关系: 传感器的机械部件包括环形凹槽转动盘 1 和相嵌合的环形凹槽固定盘 40,传感器的传感部件包括多个永磁块 2、霍尔 3、单片机 31、 数模转换器 27和运算放大器 28; 传感部件中依次相连的霍尔 3、 单片机 31、 数模转换器 27和运算放大器 28四个电子元件设在一块电路板 59上;在空心环 41的环形凹槽转动盘 1内壁固定多个永磁块 2, 在空心环 41的环形凹槽固定盘 40内壁固定电路板 59, 电路板 59上的霍尔 3设在能感受永磁块 2的磁通量, 并且霍尔 3能根据磁通量变化输出变化电 信号的位置。传感部件是传感器的传感功能部件; 机械部件是有两个功能, 第一是固定传 感部件中的各个元件的相对位置,使各个元件能组成一个传感功能性整体,第二是把这一 个传感功能性整体固定在电动自行车上,并使这个传感功能性整体能传感电动自行车的运 动状态。把依次相连的霍尔 3、单片机 31、数模转换器 27和运算放大器 28四个电子元件 设在一块电路板 59上, 有利这四个电子元件集成化、 模块化、 小型化, 方便把这四个电 子元件整体统一固定在空心环 41的环形凹槽固定盘 40内壁,使生产制造传感器的工艺简 化。  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.
本发明的传感器各部件的优选型号和具体连接方式为: 霍尔 3是 UGN3075 , 助力模 型处理器 21是 AT89S52单片机 31,数模转换器 27是 ADC-C8E;运算放大器 28是 OF-17F, OF-17F运算放大器 28的输入端 2脚与输出端 6脚之间连接有热敏电阻 R6; 各部件连接 关系如下:  The preferred model and specific connection method of the components of the sensor of the present invention are: Hall 3 is UGN3075, power model processor 21 is AT89S52 single chip 31, 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:
霍尔 3的信号输出端 3脚连接单片机 31的 12脚 INTO [P32]; The signal output terminal 3 of Hall 3 is connected to the 12-pin INTO [P32] of the single chip microcomputer 31 ;
单片机 31的 39脚 P00连接数模转换器 27的 12脚 B8; MCU 31's 39-pin P00 is connected to the digital-to-analog converter 27's 12-pin B8;
单片机 31的 38脚 P01连接数模转换器 27的 11脚 B7; Mp 31 of the MCU 31 pin P01 is connected to the digital-to-analog converter 27 of the 11-pin B7;
单片机 31的 37脚 P02连接数模转换器 27的 10脚 B6; MCU 31's 37-pin P02 is connected to the digital-to-analog converter 27's 10 feet B6;
单片机 31的 36脚 P03连接数模转换器 27的 9脚 B5 ; The 36-pin P03 of the MCU 31 is connected to the 9-pin B5 of the digital-to-analog converter 27;
单片机 31的 35脚 P04连接数模转换器 27的 8脚 B4; MCU 31's 35-pin P04 is connected to the digital-to-analog converter 27's 8-pin B4;
单片机 31的 34脚 P05连接数模转换器 27的 7脚 B3 ; The 34-pin P05 of the MCU 31 is connected to the 7-pin B3 of the digital-to-analog converter 27;
单片机 31的 33脚 P06连接数模转换器 27的 6脚 B2; The 32-pin P06 of the MCU 31 is connected to the 6-pin B2 of the digital-to-analog converter 27;
单片机 31的 32脚 P07连接数模转换器 27的 5脚 B1 ; 数模转换器 27的 4脚连接运算放大器 28的 2脚; 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;
数模转换器 27的 2脚连接运算放大器 28的 3脚; The 2-pin of the digital-to-analog converter 27 is connected to the 3 pin of the operational amplifier 28;
运算放大器 28的 6脚为模拟信号输出端。 The 6th pin of the operational amplifier 28 is the analog signal output.
OF-17F运算放大器 28的输入端 2脚与输出端 6脚之间连接有热敏电阻 R6, 而且热敏电 阻 R6两端还并联有电容 C6。 优选热敏电阻 R6为 5K, 电容 C6为 8Ρ, 数模转换器 27的 4脚与运算放大器 28的 2脚之间用 1.25k的 R5接地。 使其可用热敏电阻 R6调节运算放 大器 286脚输出的模拟信号电压范围稳定在 0.8--4.2V之间。  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. Preferably, the thermistor R6 is 5K, the capacitor C6 is 8Ρ, and 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. Make it possible to use the thermistor R6 to adjust the operational amplifier. The analog signal voltage range of the 286 pin output is stable between 0.8--4.2V.
环形凹槽固定盘 40 内圈的外表面与环形凹槽转动盘 1 内圈的内表面之间设有轴承 42。轴承 42使环形凹槽固定盘 40与环形凹槽转动盘 1之间能长时间保持良好的相对转动。  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.
传感器的环形凹槽固定盘 40外表面设有圆形凹陷 58; 圆形凹陷 58与电动自行车中 轴 51外的套管 52卡接,成套管 52卡套在圆形凹陷 58内固定连接的结构。用环形凹槽固 定盘 40的圆形凹陷 58与电动自行车中轴 51外的套管 52卡接固定有装配简单、方便清洗、 外形美观的效果。  The outer surface of the annular groove fixing plate 40 of the sensor is provided with a circular recess 58; the circular recess 58 is engaged with the sleeve 52 outside the shaft 51 of the electric bicycle, and the sleeve 52 is sleeved and fixedly connected in the circular recess 58. . The circular recess 58 of the fixing plate 40 is fixed to the sleeve 52 outside the shaft 51 of the electric bicycle, and has the advantages of simple assembly, convenient cleaning and beautiful appearance.
霍尔 3设在内圆形轨迹线与外圆形轨迹线之间。因为霍尔 3是能有间距感受永磁块 2 磁通量而输出电信号的部件, 又为了尽量减小永磁块 2的体积, 使其在环形凹槽转动盘 1 上尽量多的设置永磁块 2, 使尽量减小的永磁块 2都能被霍尔 3感应; 霍尔 3应设在内圆 形轨迹线与外圆形轨迹线之间,而且最好设在接近能贯穿全部永磁块 2的圆形轨迹线的位 置。  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.
环形凹槽转动盘 1在多个永磁块 2的内圆形轨迹线所在圆范围内设有中心孔。如果环 形凹槽转动盘 1要穿套在一个转动轴上使用,环形凹槽转动盘 1上就要设一个穿套转动轴 的孔;为保证环形凹槽转动盘 1在随转动轴转动时,霍尔 3能感受环形凹槽转动盘 1上每 个永磁块 2的运动信号,则环形凹槽转动盘 1上的穿套孔应设在多个永磁块 2的内圆形轨 迹线所在圆范围的中心, 由于内圆形轨迹线和外圆形轨迹线为同心圆, 当然穿套孔在外圆 形轨迹线所在圆范围的中心,穿套孔是内圆形轨迹线和外圆形轨迹线的中心位置孔, 即中 心孔。 也就是说, 中心孔不一定是圆形, 可以是方形、 三角形等形状, 以便可以与方形、 三角形等形状的转动轴相套,但中心孔的内空一定包括内圆形轨迹线所在圆的中心,才能 使用一个霍尔 3感受环形凹槽转动盘 1环形凹槽转动盘上全部永磁块 2的运动信号。  The annular groove rotating disk 1 is provided with a center hole in a circle in which the inner circular track 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 hole. That is to say, the center hole is not necessarily circular, and may be a square, a triangle or the like so as to be sleeved with a rotating shaft of a shape such as a square or a triangle, but the inner space of the center hole must include the circle of the inner circular trajectory. The center can use a Hall 3 to sense the motion signal of all the permanent magnet blocks 2 on the rotating disk of the annular groove rotating disk 1 to rotate the disk.
至少有一个永磁块 2的磁通量不等于其它任何一个永磁块 2的磁通量。不等于其它的 磁通量, 即特殊磁通量可用于表示自行车脚踏板的位置。 最好是至少有两个个永磁块 2 的磁通量不等于其它任何一个永磁块 2的磁通量,这两个特殊磁通量的永磁块 2分别对应 于两个脚踏板, 用于表示自行车两个脚踏板的位置。 因为自行车脚踏板的圆周运动, 判定 脚踏板位置对于获得本次圆周运动的速度, 确定下一次圆周运动的助力模型非常重要。 环形凹槽转动盘 1是不导磁材料的塑料板、铝材板、铜材板的某一种。 由于本发明是 相邻永磁块 2的磁极性相反的结构, 能使相邻永磁块 2的边缘几乎可相贴也能使霍尔 3 输出有控制功能的电信号。 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. Not equal to other magnetic fluxes, that is, special magnetic flux can be used to indicate the position of the bicycle pedal. Preferably, 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 Foot pedal position For obtaining the speed of this circular motion, it is important to determine the assist model for the next 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.
本发明的优点: 结构简单、成本低、永磁块环上的永磁块数量不受限止、输出标准的 脉冲信号、没有信号盲区、只用一个霍尔的一组输出信号就能完全表示动盘的全部运动状 态、输出信号不会失真不漂移、用永磁块的磁通量变化表示所在固定位置、输出信号中可 以有每个永磁块的运动位置,用于助力自行车,使助力输出与助力需求能高度配合而使骑 车人感觉很舒服。  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 entire motion state of the moving plate, 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.
( 1 ) 结构简单, 不用弹性件, 无机械故障: 用霍尔感受多个永磁块转动输出信号, 用中国专利 01201843.0提供的速度可推算力矩的原理, 可用多种数学模型推算助力自行 车的力矩参数, 用于控制助力自行车的电机, 实现助力。 不用弹性件、 结构简单、 成本低 于用弹性件和机械受力的传感器。 避免了长时间使用后, 各机械部件变形、 无机械故障、 配合不佳的问题。  (1) Simple structure, no elastic parts, no mechanical failure: Use Hall to feel the rotation output signal of multiple permanent magnet blocks, and use the principle of speed provided by Chinese patent 01201843.0 to calculate the torque principle. Various mathematical models can be used to calculate the torque of the bicycle. Parameters, used to control the motor that assists the bicycle to achieve power. It does not use elastic parts, has a simple structure, and is less costly than a sensor that uses elastic members and mechanical forces. It avoids the problem of deformation of various mechanical parts, no mechanical failure, and poor fit after prolonged use.
(2) 磁极性相反, 输出矩形波信号, 具有精确控制功能: 由于相邻永磁块的磁极性 相反,并且霍尔选用对相反磁极性产生矩形波输出信号的霍尔,则相邻永磁块无论间距多 少, 即使相邻永磁块之间没有间隙, 霍尔也同样能输出矩形波信号。 如用于助力自行车, 用矩形波的输出信号来控制助力自行车的电机优于用正弦波,因为矩形波能作到信号在任 何时间点,表示运动位置和速度的信号含义精确,从而可精确表示助力自行车踏板的运动 位置和速度, 以便用踏板精确的位置和速度推算出该运动状态正确的助力需求。  (2) 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. For power-assisted bicycles, it is better to use a rectangular wave output signal to control the motor of the assist bicycle than to use a sine wave, because the rectangular wave can make the signal at any point in time, and the signal indicating the position and speed of the motion is accurate, so that it can be accurately represented. 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.
( 3 ) 相邻永磁块的磁极性相反, 永磁块数量不受限止, 可尽量增加传感点位: 由于 磁极性相反, 输出矩形波信号, 相邻永磁块即使无间隙, 其输出的信号仍然是有个数、可 区分的矩形波信号,仍然具有控制功能,也就是说不会输出没有控制功能的无变化直线形 信号。如用于助力自行车, 由于与踏板联动的环形凹槽转动盘直径大小受限止, 就可在规 定大小的环形凹槽转动盘上, 尽量增加永磁块数量、尽量增加传感点位、用尽量多的传感 信号表示自行车踏板运动位置和速度, 精确表示运动状态。  (3) 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. For the purpose of assisting the bicycle, since the diameter of the rotating groove of the annular groove associated with the pedal is limited, 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.
(4) 相邻永磁块的磁极性相反, 可设置永磁块多、 传感点位多, 对环形凹槽转动盘 的运动状态表示精确:对用于助力自行车, 固定永磁块的环形凹槽转动盘大小受到严格限 止, 一般环形凹槽转动盘直径只能在 10-15厘米以内, 为了使霍尔在有间距的条件下获得 永磁块的磁极信号, 其永磁块的直径至少为 Φ 0. 6-0. 8厘米, 则直径 10-15厘米的环形凹 槽转动盘的周边无间隙的可设置 35-73 个永磁块 [ ( 10-1 ) *3.14/0.8=35 ; ( 15-1 ) *3.14/0.6=73 ], 即脚踏板转一周, 霍尔可获得 35-73个信号用于控制助力自行车的电机。 但如果是相邻永磁块磁极性相同的现有技术, 相邻永磁块按 5厘米间距, 则在直径 10-15 厘米环形凹槽转动盘上, 最多只能设置 5-8 个永磁块 [ ( 10-1 ) *3.14/5.8=5 ; ( 15-1 ) *3.14/5.6=8 ]。 可见, 本专利技术比现有技术可以多设置永磁块 7-9倍 [35/5=6; 73/8=9], 多设置 30-65个永磁块 [35-5=30; 73-8=65 ]。 所以, 环形凹槽转动盘转一周, 本专利技 术比现有技术增加了 7-9倍的环形凹槽转动盘转动位点信号。对助力自行车的电机控制精 确度自然提高了 7-9倍, 使骑车人对助力需求精确度也提高了 7-9倍, 车与人的配合程度 大大提高,骑车人的舒适感大大增加,不再是现有技术的助力车那种一快一慢不舒服的感 觉。 本发明请人根据实际的体验, 当环形凹槽转动盘上大致均勾的设置 15个永磁块时, 基本消除了现有技术只设 5-8个永磁块使助力车那种一快一慢不舒服的感觉;当环形凹槽 转动盘上大致均勾的设置 20个永磁块时, 车与人的配合己能满足人的需要, 乘骑助力车 的感觉已很舒服。 (4) 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 Φ 0. 6-0. 8 cm, the annular groove with a diameter of 10-15 cm can be set with 35-73 permanent magnet blocks without gaps around the rotating disk [ ( 10-1 ) * 3.14 / 0.8 = 35 ; ( 15-1 ) *3.14/0.6=73 ], that is, the pedals turn one week, Hall can get 35-73 signals to control the motor of the bicycle. However, if the magnetic poles of 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. Block [ ( 10-1 ) *3.14/5.8=5 ; ( 15-1 ) *3.14/5.6=8 ]. It can be seen that the patented technology can set the permanent magnet block 7-9 times more than the prior art [35/5=6; 73/8=9], and set more 30-65 permanent magnet blocks [35-5=30; 73 -8=65 ]. Therefore, the annular groove rotates the disk one turn, and the patented technology adds 7-9 times the circular groove rotating disk rotation position signal than the prior art. 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. According to the actual experience of the present invention, when 15 permanent magnet blocks are arranged on the rotating groove of the annular groove, substantially eliminating 5-8 permanent magnet blocks in the prior art, the speed of the bicycle is fastened. Slow and uncomfortable feeling; when the circular groove is roughly hooked on the rotating disk to set 20 permanent magnet blocks, the cooperation between the car and the person can satisfy the needs of the person, and the feeling of riding the bicycle is very comfortable.
( 5 )没有信号盲区,任何时候的助力需求都会获得相匹配的助力:本专利在直径 10-15 厘米的环形凹槽转动盘周边最多可设置 35-73 个永磁块, 各永磁块之间平均夹角为 5-10 度。 用于助力自行车, 在启动或运行时, 脚踏板从离开顶点 10-45度角的 35度区域内, 有 4-7个永磁块(在离开顶点 10度角的位置就有一个信号了), 则霍尔可输出 4-7个控制 信号反应助力需求,能实现任何位置、任何时间有助力就能获得相应助力的优良技术效果, 使车与人的配合良好, 骑车人感到省力又舒适。  (5) There is no signal blind zone, and the assisting demand will be matched at any time: 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. 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.
( 6) 只用一个霍尔, 一个控制信号表示环形凹槽转动盘的全部运动状态, 控制信号 与环形凹槽转动盘的运动状态完全一致,控制信号与人的需求完全一致: 多个永磁块是固 定在环形凹槽转动盘上的,永磁块与环形凹槽转动盘同步转动,用一个霍尔感受全部的永 磁块运动信号,则霍尔输出的控制信号与环形凹槽转动盘的运动状态完全一致,与人的需 求也就完全一致,控制信号不会有原始分段误差和信号漂移问题。即使霍尔传感参数发生 变化,也是整个控制信号平行移动,只要接收霍尔控制信号的电机控制器的接收范围较宽, 变化了的霍尔控制信号的控制效果成系统性改变。如用于助力自行车,助力需求模型不会 失真,助力输出与助力需求仍然保持原来模型的匹配关系,骑车人很容易掌握这种助力性 能的系统性改变。  (6) 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. As long as the receiving range of the motor controller receiving the Hall control signal is wide, the control effect of the changed Hall control signal changes systematically. If used to assist bicycles, the power demand model will not be distorted, and the power output and power demand will still maintain the original model. Cyclists can easily grasp the systematic changes of this power performance.
( 7)各永磁块的磁通量有变化,磁通量有变化的永磁块可表示特定位点的运动状态: 因为各永磁块的磁通量有变化,各永磁块使霍尔输出特有峰谷差值波形的控制信号,则特 有峰谷差值波形的控制信号就可以直接表示环形凹槽转动盘的某一固定永磁块位点的运 动状态; 如每个永磁块都有自己的特定磁通量, 可达到有多少个永磁块, 就可获得多少个 特定位点的运动状态信号。 如用于助力自行车, 环形凹槽转动盘直径在 10-15厘米以内, 环形凹槽转动盘转一周, 霍尔可获得 35-73 个不同位点运动状态的控制信号, 自然知道 35-73个位点的助力需求。 很明显, 环形凹槽转动盘转一周, 现有技术最多只能有 5-8个 助力需求, 远远不如本专利最多可用 35-73个助力需求信号更能真实地、多信息量地反应 骑车人的助力需求。 也就是说, 助力自行车用本专利技术, 车更能与人需求相配合一致, 骑车人感受到脚踏板在任何转动位置, 自己都完全可控制车速, 舒适性好。而现有技术的 助力自行车只能在最多 5-8个转动位置才能可控制车速。 (7) The magnetic flux of each permanent magnet block changes, and the permanent magnet block with varying magnetic flux can indicate the motion state of a specific site: Because the magnetic flux of each permanent magnet block changes, 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, how many can be obtained? The motion state signal of a specific site. For the purpose of assisting the bicycle, the diameter of the ring groove is within 10-15 cm, and the ring groove rotates for one turn. Hall can obtain 35-73 control signals of different position motions, naturally knowing 35-73 The boosting needs of the site. Obviously, 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-information reaction riding The driver's help needs. 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. However, the prior art assist bicycle can only control the vehicle speed in a maximum of 5-8 rotation positions.
( 8 ) 用能相对转动的环形凹槽转动盘环形凹槽固定盘合成壳体, 固定了霍尔与全部 永磁块的相对位置, 避免了壳体外的环境干扰, 提高了霍尔信号的可靠性、真实性, 还方 便了安装、 调试、 维修等。  (8) Rotating the annular groove of the disk with a relatively rotatable annular groove to fix the housing, fixing the relative position of the Hall and all the permanent magnet blocks, avoiding environmental interference outside the casing, and improving the reliability of the Hall signal. Sexuality, authenticity, and convenience for installation, commissioning, maintenance, etc.
( 9)可以对霍尔信号进行数字化处理,使控制信号中加入人机最佳配合的控制模型: 把具有磁块位置和磁块转速的矩形波信号变为该两要素的数字信号,用设定的、适合人机 配合良好的数学助力模型把该两要素的数字信号转换成助力模型数字信号,再把助力模型 数字信号转换成助力模型模拟信号,最后把助力模型模拟信号变为稳定电压范围的、具有 额定功率的电机控制器可用的控制信号。 总之, 就是把磁块转动的信号进行数字化处理, 在数字化处理处理过程中, 加入数学的助力模型, 使传感器最后输出的控制信号中, 含有 加入的助力模型。 因为数学的助力模型是人为设定的, 所以, 总可以把数学的助力模型设 定成最适合人机配合的模型, 则本发明的传感器可输出能实现最佳人机配合的控制信号。 而现有助力自行车传感器的磁块相同磁极在同一面,霍尔不能获得矩形波信号,也就无法 对霍尔信号进行数字化处理,其控制模型只能是对霍尔信号进行局部修改,所以不能实现 输出人机最佳配合的控制信号。  (9) 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 position of the magnetic block and the rotational speed of the magnetic block is changed into the digital signal of the two elements. 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. In the process of digitization processing, 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. However, 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.
最后输出的控制信号不会有信号漂移: 用热敏电阻 R6对运算放大器的输出信号进行 反馈调节,可以解决霍尔、数模转换器和运算放大器等半导体器件使助力模型模拟信号漂 移的问题, 使传感器最后输出的是不受环境温度变化的标准助力模型模拟信号。  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 problem that the semiconductor device such as Hall, digital-to-analog converter and operational amplifier makes the analog model drift signal. The final output of the sensor is a standard boost model analog signal that is unaffected by ambient temperature changes.
( 11 )能实现人机最佳配合的电机工作方式:模数转换和波峰识别器将各个矩形波信 号变为不同的数字信号,助力模型计算器就可用助力起点选择器在助力模型存储器中选定 的与助力需求最佳配合的助力数学模型,并把磁块转速计算器提供的速度参数代入助力数 学模型,助力模型计算器就能计算出脚踏板在某个位置情况下的助力模型数字信号。该助 力模型数字信号就是能使人与电动自行车能最佳配合的、用于控制电机用的控制信号。助 力模型计算器是数字处理器,它能接受任何数字化的数学模型,则助力模型存储器就可以 向助力模型计算器提供任何人为设定的数学模型,有了人任意设定数学模型这个条件,人 就可以设定能使人与电动自行车能最佳配合的数学模型。助力模型存储器有人设定的,能 使人与电动自行车能最佳配合的数学模型,则就能实现人与电动自行车最佳配合的电机工 作方式; 人设定数学模型还可以使电机有最合理的启动和运转模型、 最省电的工作方式。 所以, 本发明的助力自行车是人与电动自行车最佳配合的省电助力自行车。 (11) The working mode of the motor that can achieve the best cooperation between man and machine: the analog-to-digital conversion and the peak recognizer convert each rectangular wave signal into a different digital signal, and the assist model calculator can be selected in the assist model memory by the assist starting point selector. The assisted mathematical model that best matches the boosting demand, and the speed parameter provided by the magnetic block speed calculator is substituted into the assisting mathematical model, and the assist model calculator can calculate the assisting model number of the pedal in a certain position. signal. The power model digital signal is a control signal for controlling the motor to best match the electric bicycle. The power model calculator is a digital processor that can accept any digitized mathematical model. The power model memory can provide any artificially set mathematical model to the power model calculator. It is possible to set up a mathematical model that best matches the person with the electric bicycle. The mathematical model set by the power model memory that can best match the electric bicycle with the electric bicycle can realize the best working mode of the motor with the electric bicycle. The mathematical model can also make the motor most reasonable. Start and run models, the most energy efficient way of working. Therefore, the assist bicycle of the present invention is a power-saving bicycle that is optimally matched with an electric bicycle.
但现有助力自行车脚踏板的一个转动周期内, 霍尔只能输出不到 10个正弦波信号, 正弦波信号不能变为数字信号,不能人为加入最佳助力模型控制电动自行车的电机,这种 助力自行车的助力模型即不能实现人机最佳配合,也不能使电机有最合理、省电的工作方 式。  However, in one rotation cycle of the existing bicycle pedal, Hall can only output less than 10 sine wave signals, and the sine wave signal cannot be converted into a digital signal. It is impossible to artificially add the optimal power model to control the electric bicycle motor. The power assist model of the bicycle can not achieve the best fit of the man-machine, nor can the motor have the most reasonable and power-saving working mode.
( 12)省电效果和意义:用本发明的助力自行车与市上购买的有 8个永磁块同面为相 同磁极作为传感部件的助力自行车进行省电比较,用同一个电动自行车换用不同传感器的 方式, 相同的骑车人在相同路段乘骑测实, 结果是: 用本发明的助力自行车乘骑 110公里 后, 电池还余有少量的电; 但用该市上购买的助力自行车乘骑 45公里后, 电池已没有余 电。该省电的意义在于: 充满电的本发明的助力自行车能满足全天乘骑不充电, 解决了人 在途中而车已不能助力这个现有助力自行车的大难题。  (12) Power saving effect and significance: The power-assisted bicycle of the present invention is compared with the commercially available power-assisted bicycle with the same magnetic pole as the sensing component on the same magnetic pole block, and the same electric bicycle is used for replacement. In the way of different sensors, the same rider rides on the same road section and the result is: After riding the 110 km of the assisted bicycle of the invention, the battery still has a small amount of electricity; but with the booster bicycle purchased in the city After riding for 45 kilometers, there is no battery left. The significance of the power saving is that the fully-powered bicycle of the present invention can satisfy the whole day riding without charging, and solves the big problem that the bicycle is unable to assist the existing assist bicycle on the way.
附图说明 DRAWINGS
图 1是环形凹槽转动盘上多磁块位置不均勾分布磁通量, 且永磁块 N-S交替的传感元件 结构示意图, 图中永磁块线条粗细不同表示磁通量不同; 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;
图 2是环形凹槽转动盘上多磁块位置不均勾分布磁通量, 且高密度的永磁块成 N-S交替 的传感元件结构示意图, 图中永磁块线条粗细不同表示磁通量不同; 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;
图 3是自行车的中轴和套管与传感器连接关系的剖面结构示意图; 3 is a schematic cross-sectional structural view showing a relationship between a center axis of a bicycle and a sleeve and a sensor;
图 4是霍尔、 助力模型处理器、 数模转换器、 运算放大器的信号流向方框图; 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;
图 5是霍尔、 单片机、 数模转换器、 运算放大器的电路图; Figure 5 is a circuit diagram of a Hall, a microcontroller, a digital-to-analog converter, and an operational amplifier;
图 6是传感器设在电动自行车的中轴上组成本发明助力自行车的连接关系示意图。 Fig. 6 is a schematic view showing the connection relationship of the sensor provided on the center shaft of the electric bicycle to constitute the assist bicycle of the present invention.
图中 1是环形凹槽转动盘、 2是永磁块、 3是霍尔、 5是圆形轨迹线、 21是助力模型处理 器、 22是模数转换和波峰识别器、 23是助力起点选择器、 24是磁块转速计算器、 25是助 力模型存储器、 26是助力模型计算器、 27是数模转换器、 28是运算放大器、 29是电机控 制器、 30是电机、 31是单片机、 32是时钟电路、 40是环形凹槽固定盘、 41是空心环、 42是轴承、 51是中轴、 52是套管、 53是链盘、 54是脚踏板、 55是电池、 58是圆形凹陷、 59是电路板。 In the figure, 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, and 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 controller, 30 is the motor, 31 is the microcontroller, 32 Is the clock circuit, 40 is the annular groove fixed disk, 41 is the hollow ring, 42 is the bearing, 51 is the center shaft, 52 is the sleeve, 53 is the chain plate, 54 is the foot pedal, 55 is the battery, 58 is the circle The recess, 59 is the circuit board.
具体实施方式 detailed description
实施例 1、 用壳体内多磁块不均勾分布磁通量传感器的助力自行车 如图 1、 3、 4、 6, 把本发明中的传感器安装在现有的电动自行车的中轴 51上, 将传感器 的信号输出线与电动自行车的电机控制器 29连接, 就得到本发明的助力自行车。 Embodiment 1. A power bicycle with a magnetic flux sensor distributed unevenly by a multi-magnetic block in a casing 1, 3, 4, 6, the sensor of the present invention is mounted on the center shaft 51 of the existing electric bicycle, and the signal output line of the sensor is connected to the motor controller 29 of the electric bicycle, thereby obtaining the present invention. Power bicycles.
一、 与安装传感器有关的电动自行车部件和结构: 电动自行车有中轴 51, 中轴 51中间段 套有套管 52, 中轴 51与套管 52转动连接; 中轴 51上固定有链盘 53, 中轴 51两端分别 固定有脚踏板 54; 套管 52的内表面与中轴 51转动连接, 套管 52的外表面与电动自行车 的车架固定连接; 电动自行车上电池 55连接电机控制器 29, 电机控制器 29连接车轮上 的电机 30。 First, the electric bicycle component and structure related to the installation of the sensor: The electric bicycle has a middle shaft 51, the middle portion 51 has a sleeve 52 in the middle portion, and the middle shaft 51 is rotatably connected with the sleeve 52; the chain shaft 53 is fixed on the central shaft 51. The inner shaft 51 is respectively fixed with a foot pedal 54; the inner surface of the sleeve 52 is rotatably connected with the central shaft 51, and the outer surface of the sleeve 52 is fixedly connected with the frame of the electric bicycle; the electric battery 55 is connected to the motor control The motor controller 29 is coupled to the motor 30 on the wheel.
二、 传感器的结构和部件的连接关系如下: Second, the structure of the sensor and the connection relationship of the components are as follows:
传感器包括依次连接的传感元件、 助力模型处理器 21、 数模转换器 27和运算放大器 28; The sensor comprises a sensing element connected in sequence, a boost model processor 21, a digital to analog converter 27 and an operational amplifier 28;
[ 1 ] 传感元件是把环形凹槽转动盘 1的转动运动变为矩形波信号输出的元件;  [1] The sensing element is an element that changes the rotational motion of the annular groove rotating disk 1 into a rectangular wave signal output;
用一个环形凹槽转动盘 1和一个环形凹槽固定盘 40两者的凹面相对, 环形凹槽转动 盘 1和环形凹槽固定盘 40的大小正好使环形凹槽固定盘 40能嵌合在环形凹槽转动盘 1 的环形凹槽之中,合成两个盘能相对转动的嵌合内空外壳,两个盘的凹面夹成一个空心环 41; 在空心环 41位置的环形凹槽转动盘 1上固定设置有 20个永磁块 2。环形凹槽转动盘 1和环形凹槽固定盘 40用高强度塑料注塑成形。  With the concave surface of both the annular groove rotating disk 1 and an annular groove fixing disk 40, 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 There are 20 permanent magnet blocks 2 fixed on the top. The annular groove rotating disk 1 and the annular groove fixing disk 40 are injection molded from high-strength plastic.
空心环 41内的环形凹槽转动盘 1面直径 10. 0厘米, 在环形凹槽转动盘 1设 20个永 磁块 2, 20个永磁块 2的直径分别为 0. 8厘米的, 磁通量为 146---279(B · H)max/KJ · m"3 范围内不同的选择值, 并且相临永磁块 2的磁通量不相等。环形凹槽转动盘 1、永磁块 2、 霍尔 3的结构如下: 8厘米的磁磁量, 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:
全部永磁块 2均勾地呈圆形轨迹分布,每个永磁块 2固定在直径 9.0厘米圆形轨迹线 All permanent magnet blocks 2 are distributed in a circular trajectory, and each permanent magnet block 2 is fixed on a circular trajectory with a diameter of 9.0 cm.
5上, 即每个永磁块 2到圆形轨迹线 5所在圆中心的距离相同、相邻永磁块 2之间的距离 相同。 5, that is, the distance between each permanent magnet block 2 to the center of the circle where the circular trajectory line 5 is located is the same, and the distance between the adjacent permanent magnet blocks 2 is the same.
有两个永磁块 2的磁通量不等于其它任何一个永磁块 2的磁通量,而且这两个永磁块 2的磁通量也不相等, 该两个永磁块 2的位置正好在环形凹槽转动盘 1一条直径的两端, 这两个永磁块 2用于在助力自行车上表示两个脚踏板的运动位置。  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 magnetic fluxes of the two permanent magnet blocks 2 are also not equal, and the positions of the two permanent magnet blocks 2 are exactly rotated in the annular groove. The disk 1 has two ends of a diameter, and the two permanent magnet blocks 2 are used to indicate the moving position of the two foot pedals on the assist bicycle.
在环形凹槽转动盘 1一个面设置的全部永磁块 2成相邻永磁块 2的磁极性相反的方式 排列, 即环形凹槽转动盘 1一个面上全部永磁块 2的磁极性分布方式是 N极、 S极、 N 极、 S极、 N极、 S极……。  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 modes are N pole, S pole, N pole, S pole, N pole, S pole...
在空心环 41内的环形凹槽固定盘 40上固定设置有一个霍尔 3,霍尔 3的信号输出线 从环形凹槽固定盘 40穿出, 霍尔 3设在接近永磁块 2的位置, 即霍尔 3设在每个永磁块 2所在圆形轨迹线 5范围内,霍尔 3与转动状态的每个永磁块 2保持 0.3厘米的间隔距离, 使转动的每个永磁块 2在经过霍尔 3时, 霍尔 3能产生一个对应的矩形波电信号输出。 环形凹槽转动盘 1在该全部永磁块 2所在圆形轨迹线 5中心设有中心孔,中心孔用于 套在助力自行车的踏板中轴 51上。 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. , that is, 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 is kept at a distance of 0.3 cm from each of the permanent magnet blocks 2 in the rotating state. When each of the permanent magnet blocks 2 that are rotated passes through the Hall 3, the Hall 3 can generate a corresponding rectangular wave electric signal output. The annular groove rotating disk 1 is provided with a center hole at the center of the circular trajectory line 5 where the permanent magnetic block 2 is located, and the center hole is for fitting on the pedal center shaft 51 of the assist bicycle.
[2]助力模型处理器 21是把环形凹槽转动盘 1转动的数字信号变为助力模型数字信号的 信号形式的转换器;  [2] The assist model processor 21 is a converter that converts the digital signal rotated by the annular groove rotating disk 1 into a signal form of the assist model digital signal;
助力模型处理器 21包括模数转换和波峰识别器 22、助力起点选择器 23、磁块转速计 算器 24、 助力模型存储器 25和助力模型计算器 26;  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;
模数转换和波峰识别器 22与传感元件连接,模数转换和波峰识别器 22把传感元件中 霍尔 3输入的矩形波信号进行识别各个矩形波的波峰,将各个矩形波信号变为不同的数字 信号, 对每个矩形波进行标注, 模数转换和波峰识别器 22输出标注有磁块位置秩序的磁 块运动数字信号;  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;
模数转换和波峰识别器 22分别与助力起点选择器 23和磁块转速计算器 24连接, 助 力起点选择器 23与磁块转速计算器 24连接; 磁块转速计算器 24用模数转换和波峰识别 器 22输入的磁块运动数字信号计算出环形凹槽转动盘 1的转速, 并把环形凹槽转动盘 1 的转速数字信号传给助力起点选择器 23,助力起点选择器 23用标注有磁块位置秩序的磁 块运动数字信号,和环形凹槽转动盘 1的转速数字信号这两个信号确定在某种转速条件下 的助力起点对应的某一个矩形波, 即确定助力起点磁块; 助力起点选择器 23完成了找出 助力的起始点磁块,也就是确定从某个矩形波开始实施助力,准确说就是在环形凹槽转动 盘 1处于某种转速条件下,从某个磁块在某个位置开始进行助力,或是从某个磁块在某个 位置开始, 将原来的助力模型改变为下一步选择的助力模型进行助力。  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.
助力起点选择器 23和磁块转速计算器 24分别都与助力模型计算器 26连接, 助力模 型存储器 25也与助力模型计算器 26连接;助力模型计算器 26用助力起点选择器 23的助 力起点磁块, 和用磁块转速计算器 24的环形凹槽转动盘 1转速这两个条件选择助力模型 存储器 25中的某一种助力模型函数, 并将助力起点磁块和环形凹槽转动盘 1转速这两个 条件代入助力模型函数,计算出适合这两个条件的助力模型数字信号, 即助力模型计算器 26输出助力模型数字信号;  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;
[3 ] 数模转换器 27是把助力模型数字信号转换成助力模型的模拟信号。  [3] The digital-to-analog converter 27 is an analog signal that converts the power-assisted model digital signal into a power-assisted model.
助力模型计算器 26与数模转换器 27连接,数模转换器 27把助力模型计算器 26的助 力模型数字信号转换成助力模型模拟信号。 以便向只能处理模拟信号的电机控制器 29输 出助力模型的模拟信。  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.
[4] 运算放大器 28是把数模转换器 27的助力模型模拟信号转换成额定电压范围的助力 模型模拟信号。 [4] The operational amplifier 28 is a booster that converts the assist model analog signal of the digital-to-analog converter 27 into a rated voltage range. Model analog signal.
数模转换器 27与运算放大器 28连接, 数模转换器 27的助力模型模拟信号虽然解决 了助力模型问题, 但助力模型信号的电压还不能满足电机控制器 29的需要, 所以还要用 运算放大器 28把助力模型模拟信号转换成额定电压范围需要的助力模型模拟信号, 才能 传输给电机控制器 29, 达到电机控制器 29控制电机 30进行助力为目的的运行。  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. 28 The auxiliary model analog signal required to convert the assist model analog signal into the rated voltage range 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.
三、传感器与电动自行车的连接成助力自行车:把传感器的环形凹槽转动盘 1和环形凹槽 固定盘 40套在电动自行车的中轴 51外, 并且环形凹槽固定盘 40与中轴 51外的套管 52 固定连接, 传感器的环形凹槽转动盘 1与电动自行车的中轴 51固定连接, 环形凹槽转动 盘 1伴随中轴 51同步转动;环形凹槽转动盘 1与环形凹槽固定盘 40内外相套的嵌合成转 动连接; 环形凹槽转动盘 1和中轴 51两者为相同的转动中心, 传感器中运算放大器 28 的信号输出导线与电动自行车的电机控制器 29的信号输入端连接。 这样, 环形凹槽转动 盘 1上的永磁块 2伴随中轴 51同步转动,永磁块 2就与自行车脚踏板 54同步转动,永磁 块 2的转动就与脚踏板 54转动相同角度、相同速度。环形凹槽固定盘 40上的霍尔 3就通 过感受永磁块 2的转动而感受到脚踏板 54转动角度和速度。 霍尔 3把感受永磁块 2转动 的位置和速度电信号,即代表脚踏板 54转动的位置和速度电信号传给电路板 59上的电子 部件助力模型处理器 21、 数模转换器 27和运算放大器 28进行信号处理。 运算放大器 28 与电动自行车的电机控制器 29连接, 实现了传感器用电信号控制电动自行车的目的, 即 用运算放大器 28的助力模型模拟信号, 或称标准助力模型模拟信号控制电动自行车, 得 到助力自行车。 3. Connecting the sensor to the electric bicycle to assist the bicycle: the annular groove rotating disk 1 and the annular groove fixing plate 40 of the sensor are sleeved outside the middle shaft 51 of the electric bicycle, and the annular groove fixing plate 40 and the central shaft 51 are externally The sleeve 52 is fixedly connected, the annular groove rotating disk 1 of the sensor is fixedly connected with the middle shaft 51 of the electric bicycle, the annular groove rotating disk 1 is synchronously rotated with the middle shaft 51; the annular groove rotating disk 1 and the annular groove fixing plate 40 inner and outer phase sleeves are fitted into a rotational connection; the annular groove rotating disk 1 and the central axis 51 are the same center of rotation, and the signal output wire of the operational amplifier 28 in the sensor is connected to the signal input end of the motor controller 29 of the electric bicycle. . Thus, the permanent magnet block 2 on the annular groove rotating disk 1 rotates synchronously with the center shaft 51, and the permanent magnet block 2 rotates synchronously with the bicycle foot pedal 54, and the rotation of the permanent magnet block 2 rotates at the same angle as the foot pedal 54. The same speed. The Hall 3 on the annular groove fixing disk 40 senses the rotation angle and speed of the foot pedal 54 by sensing the rotation of the permanent magnet block 2. The Hall 3 transmits the position and speed electric signals that sense the rotation of the permanent magnet block 2, that is, the position and speed electric signals representing the rotation of the footrest 54 to the electronic component assist model processor 21 on the circuit board 59, and the digital-to-analog converter 27. The operational amplifier 28 performs signal processing. The operational amplifier 28 is connected to the motor controller 29 of the electric bicycle, and realizes the purpose of controlling the electric bicycle by the electric signal of the sensor, that is, using the power assist model of the operational amplifier 28 to simulate the signal, or the standard assist model analog signal to control the electric bicycle, and obtaining the assist bicycle .
由于运算放大器 28输出的助力模型模拟信号是能使助力自行车电机 30运动与骑车人 的助力需求相一致的信号, 所以, 本实施例的助力自行车是人机能相配合的助力自行车。 实施例 2、 高密度用壳体内多磁块不均勾分布磁通量传感器的助力自行车  Since the assist model analog signal output from the operational amplifier 28 is a signal that can assist the bicycle motor 30 to move in accordance with the driver's assisting demand, the assist bicycle of the present embodiment is a assist bicycle in which the human function is matched. Embodiment 2. A high-density bicycle with a multi-magnetic block in a housing and a magnetic flux sensor
如图 2、 3、 4、 6, 空心环 41内的环形凹槽转动盘 1面直径 10. 0厘米, 在环形凹槽 转动盘 1 设 40 个永磁块 2, 40 个永磁块 2 的直径分别为 0. 6 厘米的, 磁通量为 146-279(B · H)max/KJ · m"3范围内不同的选择值, 并且相临永磁块 2的磁通量不相等。 霍尔 3与转动状态的每个永磁块 2保持 0.2厘米的间隔距离,使转动的每个永磁块 2在经 过霍尔 3时, 霍尔 3能产生一个对应的矩形波电信号输出。 其它环形凹槽转动盘 1、 永磁 块 2、 霍尔 3的结构同于实施例 1。 2, 3, 4, 6, the annular groove in the hollow ring 41 rotates the disk 1 surface diameter of 10. 0 cm, in the ring groove rotating disk 1 set 40 permanent magnet blocks 2, 40 permanent magnet blocks 2 The diameters are 0.6 cm, the magnetic flux is 146-279 (B · H) max / KJ · m" 3 different selection values, and the magnetic flux adjacent to the permanent magnet block 2 is not equal. Hall 3 and rotation Each permanent magnet block 2 of the state 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 rotation The structure of the disk 1, the permanent magnet block 2, and the Hall 3 is the same as that of the embodiment 1.
实施例 3、 有具体电路的用壳体内多磁块不均勾分布磁通量传感器的助力自行车 如图 1、 3、 5、 6, 如实施例 1, 传感器包括依次连接的传感元件、 助力模型处理器 21、 数模转换器 27和运算放大器 28; [ 1 ]传感元件中的霍尔 3选用 UGN3075; 传感元件中其它的元件和元件的结构同于实施 例 1 ; Embodiment 3, a bicycle having a specific circuit, and a multi-magnetic block in the casing, which distributes the magnetic flux sensor, as shown in FIGS. 1, 3, 5, and 6, as in Embodiment 1, the sensor includes a sensor element sequentially connected, and a power assist model is processed. 21, digital to analog converter 27 and operational amplifier 28; [1] Hall 3 in the sensing element selects UGN3075; the other elements and components in the sensing element have the same structure as in Embodiment 1;
[2] 助力模型处理器 21 选用单片机 31 完成全部功能, 单片机 31 选用 AT89S52。 即 AT89S52单片机 31完成模数转换和波峰识别器 22、 助力起点选择器 23、 磁块转速计算 器 24、 助力模型存储器 25和助力模型计算器 26的全部功能。  [2] 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.
[3 ] 数模转换器 27选用 ADC-C8E。  [3] Digital-to-analog converter 27 uses ADC-C8E.
[4] 运算放大器 28选用 OF-17F, OF-17F运算放大器 28的输入端 2脚与输出端 6脚之 间连接有 5k的热敏电阻 R6; 而且热敏电阻 R6两端还并联有 8P电容 C6。数模转换器 27 的 4脚与运算放大器 28的 2脚之间用 1.25k的 R5接地。 使其可用热敏电阻 R6调节运算 放大器 286脚输出的模拟信号电压范围稳定在 0.8--4.2V之间。  [4] 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.
各电子部件连接关系如下: The connection relationship of each electronic component is as follows:
霍尔 3的信号输出端 3脚连接单片机 31的 12脚 INTO [P32]; The signal output terminal 3 of Hall 3 is connected to the 12-pin INTO [P32] of the single chip microcomputer 31 ;
单片机 31的 39脚 P00连接数模转换器 27的 12脚 B8; MCU 31's 39-pin P00 is connected to the digital-to-analog converter 27's 12-pin B8;
单片机 31的 38脚 P01连接数模转换器 27的 11脚 B7; Mp 31 of the MCU 31 pin P01 is connected to the digital-to-analog converter 27 of the 11-pin B7;
单片机 31的 37脚 P02连接数模转换器 27的 10脚 B6; MCU 31's 37-pin P02 is connected to the digital-to-analog converter 27's 10 feet B6;
单片机 31的 36脚 P03连接数模转换器 27的 9脚 B5 ; The 36-pin P03 of the MCU 31 is connected to the 9-pin B5 of the digital-to-analog converter 27;
单片机 31的 35脚 P04连接数模转换器 27的 8脚 B4; MCU 31's 35-pin P04 is connected to the digital-to-analog converter 27's 8-pin B4;
单片机 31的 34脚 P05连接数模转换器 27的 7脚 B3 ; The 34-pin P05 of the MCU 31 is connected to the 7-pin B3 of the digital-to-analog converter 27;
单片机 31的 33脚 P06连接数模转换器 27的 6脚 B2; The 32-pin P06 of the MCU 31 is connected to the 6-pin B2 of the digital-to-analog converter 27;
单片机 31的 32脚 P07连接数模转换器 27的 5脚 B1; The 32-pin P07 of the MCU 31 is connected to the digital-to-analog converter 27 of the 5 pin B1;
数模转换器 27的 4脚连接运算放大器 28的 2脚; The 4-pin of the digital-to-analog converter 27 is connected to the 2 pin of the operational amplifier 28;
数模转换器 27的 2脚连接运算放大器 28的 3脚; The 2-pin of the digital-to-analog converter 27 is connected to the 3 pin of the operational amplifier 28;
运算放大器 28的 6脚为模拟信号输出端。 The 6th pin of the operational amplifier 28 is the analog signal output.
[5 ] 传感器的机械部件与传感部件结构关系: 传感器的机械部件包括环形凹槽转动盘 1 和相嵌合的环形凹槽固定盘 40,传感器的传感部件包括多个永磁块 2、霍尔 3、单片机 31、 数模转换器 27和运算放大器 28; 传感部件中依次相连的霍尔 3、 单片机 31、 数模转换器 [5] Structural relationship between the mechanical component of the sensor and 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 Hall 3, single chip microcomputer 31, digital to analog converter 27 and operational amplifier 28; Hall 3, single chip microcomputer 31, digital to analog converter connected in sequence in the sensing unit
27和运算放大器 28四个电子元件设在一块电路板 59上;在空心环 41的环形凹槽转动盘27 and operational amplifier 28 four electronic components are provided on a circuit board 59; the annular groove in the hollow ring 41 is rotated
1内壁固定多个永磁块 2, 在空心环 41的环形凹槽固定盘 40内壁固定电路板 59, 电路板1 The inner wall is fixed with a plurality of permanent magnet blocks 2, and the circuit board 59 is fixed on the inner wall of the annular groove fixing plate 40 of the hollow ring 41, the circuit board
59上的霍尔 3设在能感受永磁块 2的磁通量, 并且霍尔 3能根据磁通量变化输出变化电 信号的位置。传感部件是传感器的传感功能部件; 机械部件是有两个功能, 第一是固定传 感部件中的各个元件的相对位置,使各个元件能组成一个传感功能性整体,第二是把这一 个传感功能性整体固定在电动自行车上,并使这个传感功能性整体能传感电动自行车的运 动状态。把依次相连的霍尔 3、单片机 31、数模转换器 27和运算放大器 28四个电子元件 设在一块电路板 59上, 有利这四个电子元件集成化、 模块化、 小型化, 方便把这四个电 子元件整体统一固定在空心环 41的环形凹槽固定盘 40内壁,使生产制造传感器的工艺简 The Hall 3 on 59 is set to sense the magnetic flux of the permanent magnet block 2, 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 The sensing function is integrally fixed to the electric bicycle, and the sensing function as a whole can 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 plate 40 of the hollow ring 41, so that the process for manufacturing the sensor is simplified.

Claims

权 利 要 求 Rights request
1、 用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 包括电动自行车和传感器, 电动自行车有中轴 (51), 中轴 (51) 中间段套有套管 (52), 中轴 (51)与套管 (52)转 动连接; 中轴 (51)上固定有链盘(53), 中轴 (51)两端分别固定有脚踏板(54); 电动 自行车上电池 (55) 连接电机控制器 (29), 电机控制器 (29) 连接车轮上的电机 (30); 其特征在于: 1. A power-assisted bicycle that uses multiple magnet blocks in the housing to hook unevenly distributed magnetic flux sensors, including an electric bicycle and a sensor. The electric bicycle has a central axis (51), and the central axis (51) is covered with a sleeve (52) in the middle section. (51) is rotationally connected to the casing (52); a chain plate (53) is fixed on the central shaft (51), and pedals (54) are fixed on both ends of the central shaft (51); a battery (55) is mounted on the electric bicycle Connected to the motor controller (29), the motor controller (29) is connected to the motor (30) on the wheel; it is characterized by:
传感器的结构和部件的连接关系如下: The structure of the sensor and the connection relationship between the components are as follows:
包括依次连接的传感元件、 助力模型处理器 (21)、 数模转换器 (27) 和运算放大器 (28); It includes a sensing element, a boost model processor (21), a digital-to-analog converter (27) and an operational amplifier (28) connected in sequence;
[1] 传感元件是把环形凹槽转动盘 (1) 的转动运动变为矩形波信号输出的元件; [1] The sensing element is an element that converts the rotational motion of the annular groove rotating disk (1) into a rectangular wave signal output;
传感元件包括一块环形凹槽转动盘(1)、 环形凹槽固定盘(40)、 一个霍尔 (3)和多 枚永磁块 (2), 环形凹槽转动盘 (1) 和环形凹槽固定盘 (40) 两者的凹面相对, 环形凹 槽固定盘 (40) 嵌合在环形凹槽转动盘 (1) 的环形凹槽之中, 成两个盘能相对转动的嵌 合内空外壳, 两个盘的凹面夹成一个空心环 (41); 在空心环 (41) 位置的环形凹槽转动 盘(1)上固定设置有多枚永磁块(2), 该多枚永磁块(2)均勾地呈圆形轨迹分布, 即每 枚永磁块 (2) 到圆形轨迹线 (5) 所在圆中心的距离相同、 相邻永磁块 (2) 之间的距离 相同; 相邻永磁块 (2) 的磁极性相反, 环形凹槽转动盘 (1) 上全部永磁块 (2) 的磁极 性分布方式是 N极、 S极、 N极、 S极、 N极、 S极……; 至少有两枚永磁块 (2) 的 磁通量不相同; The sensing element includes an annular groove rotating disk (1), an annular groove fixed disk (40), a Hall (3) and a plurality of permanent magnet blocks (2). The annular groove rotating disk (1) and the annular groove The concave surfaces of the groove fixed disk (40) are opposite to each other, and the annular groove fixed disk (40) is fitted in the annular groove of the annular groove rotating disk (1), forming an inner space where the two disks can rotate relative to each other. Shell, the concave surfaces of the two disks are sandwiched into a hollow ring (41); a plurality of permanent magnet blocks (2) are fixedly provided on the annular groove rotating disk (1) at the position of the hollow ring (41), and the plurality of permanent magnets are The blocks (2) are evenly distributed in a circular trajectory, that is, the distance between each permanent magnet block (2) and the center of the circle where the circular trajectory line (5) is located is the same, and the distance between adjacent permanent magnet blocks (2) is the same. ; The magnetic polarities of adjacent permanent magnet blocks (2) are opposite, and the magnetic polarity distribution pattern of all permanent magnet blocks (2) on the annular groove rotating disk (1) is N pole, S pole, N pole, S pole, N pole , S pole...; At least two permanent magnet blocks (2) have different magnetic fluxes;
在空心环 (41) 的环形凹槽固定盘 (40) 上固定设置有一个霍尔 (3), 霍尔 (3) 设 在接近永磁块(2)并能感受每个永磁块(2)磁通量的位置, 霍尔 (3)与永磁块(2)之 间有间距; 霍尔 (3) 是对相反磁极性产生矩形波输出信号的霍尔; A Hall (3) is fixedly provided on the annular groove fixed disk (40) of the hollow ring (41). The Hall (3) is located close to the permanent magnet blocks (2) and can sense each permanent magnet block (2). ) The position of the magnetic flux, there is a distance between Hall (3) and the permanent magnet block (2); Hall (3) is a Hall that generates a square wave output signal for opposite magnetic polarity;
[2]助力模型处理器(21)是把环形凹槽转动盘(1)转动的数字信号变为助力模型数字 信号的信号形式转换器; [2] The assist model processor (21) is a signal form converter that converts the digital signal of the rotation of the annular groove rotating disk (1) into the assist model digital signal;
助力模型处理器(21)包括模数转换和波峰识别器(22)、 助力起点选择器(23)、 磁 块转速计算器 (24)、 助力模型存储器 (25) 和助力模型计算器 (26); The boost model processor (21) includes an analog-to-digital conversion and wave peak identifier (22), a boost starting point selector (23), a magnet rotation speed calculator (24), a boost model memory (25) and a boost model calculator (26) ;
模数转换和波峰识别器(22)与传感元件连接, 模数转换和波峰识别器(22)把传感 元件中霍尔 (3) 输入的矩形波信号进行识别各个矩形波的波峰, 将各个矩形波信号变为 不同的数字信号, 对每个矩形波进行标注, 模数转换和波峰识别器(22)输出标注有磁块 位置秩序的磁块运动数字信号; The analog-to-digital conversion and peak identifier (22) is connected to the sensing element. The analog-to-digital conversion and peak identifier (22) identifies the peak of each rectangular wave from the rectangular wave signal input by the Hall (3) in the sensing element. Each rectangular wave signal is changed into a different digital signal, each rectangular wave is marked, and the analog-to-digital conversion and wave peak identifier (22) outputs a magnetic block movement digital signal marked with the position order of the magnetic block;
模数转换和波峰识别器 (22) 分别与助力起点选择器 (23) 和磁块转速计算器 (24) 连接, 助力起点选择器(23 )与磁块转速计算器(24)连接; 磁块转速计算器(24)用模 数转换和波峰识别器(22)输入的标注有磁块位置秩序的磁块运动数字信号计算出环形凹 槽转动盘( 1 )的转速,并把环形凹槽转动盘( 1 )的转速数字信号传给助力起点选择器(23 ), 助力起点选择器(23 )用标注有磁块位置秩序的磁块运动数字信号,和环形凹槽转动盘(1 ) 的转速数字信号这两个信号确定在某种转速条件下的助力起点对应的某一个矩形波,即确 定助力起点磁块; Analog-to-digital converter and peak identifier (22) respectively with boost start point selector (23) and magnet speed calculator (24) Connect, the boost starting point selector (23) is connected to the magnet rotation speed calculator (24); the magnet rotation speed calculator (24) uses the analog-to-digital conversion and the wave peak identifier (22) to input the magnet block marked with the position order of the magnet block. The motion digital signal calculates the rotation speed of the annular groove rotating disk (1), and transmits the rotation speed digital signal of the annular groove rotating disk (1) to the boost starting point selector (23). The boost starting point selector (23) is marked with The two signals of the magnetic block movement digital signal of the magnetic block position order and the rotational speed digital signal of the annular groove rotating disk (1) determine a certain rectangular wave corresponding to the starting point of the assist under a certain rotational speed condition, that is, the magnetic starting point of the assist is determined. piece;
助力起点选择器(23 )和磁块转速计算器(24)分别都与助力模型计算器(26)连接, 助力模型存储器(25 )也与助力模型计算器(26)连接; 助力模型计算器(26)用助力起 点选择器 (23 ) 的助力起点磁块, 和用磁块转速计算器 (24) 的环形凹槽转动盘 (1 ) 转 速这两个条件选择助力模型存储器(25 )中的某一种助力模型函数, 并将助力起点磁块和 环形凹槽转动盘 (1 ) 转速这两个条件代入助力模型函数, 计算出适合这两个条件的助力 模型数字信号, 即助力模型计算器 (26) 输出助力模型数字信号; The boost starting point selector (23) and the magnet speed calculator (24) are respectively connected to the boost model calculator (26), and the boost model memory (25) is also connected to the boost model calculator (26); the boost model calculator (26) 26) Use the two conditions of the boost starting point magnet of the boost starting point selector (23) and the rotation speed of the annular groove rotating disk (1) of the magnet speed calculator (24) to select a certain one in the boost model memory (25). A power-assist model function, and substitutes the two conditions of the power-assist starting point magnet and the rotation speed of the annular groove rotating disk (1) into the power-assist model function, and calculates the power-assist model digital signal suitable for these two conditions, that is, the power-assist model calculator ( 26) Output the digital signal of the assist model;
[3 ] 数模转换器 (27) 是把助力模型数字信号转换成助力模型的模拟信号; [3] The digital-to-analog converter (27) converts the digital signal of the assist model into the analog signal of the assist model;
助力模型计算器(26)与数模转换器(27)连接, 数模转换器(27)把助力模型计算 器 (26) 的助力模型数字信号转换成助力模型模拟信号; The boost model calculator (26) is connected to the digital-to-analog converter (27), and the digital-to-analog converter (27) converts the boost model digital signal of the boost model calculator (26) into a boost model analog signal;
[4] 运算放大器 (28) 是把数模转换器 (27) 的助力模型模拟信号转换成额定电压范围 的助力模型模拟信号; [4] The operational amplifier (28) converts the boost model analog signal of the digital-to-analog converter (27) into a boost model analog signal within the rated voltage range;
传感器与电动自行车的连接关系是: 传感器的环形凹槽转动盘 (1 ) 和环形凹槽固定 盘(40)套在电动自行车的中轴 (51 )夕卜, 并且环形凹槽固定盘(40)与中轴 (51 )外的 套管 (52) 固定连接, 传感器的环形凹槽转动盘 (1 ) 与电动自行车的中轴 (51 ) 固定连 接, 环形凹槽转动盘(1 )伴随中轴 (51 ) 同步转动; 环形凹槽转动盘(1 )与环形凹槽固 定盘 (40) 内外相套的嵌合成转动连接; 环形凹槽转动盘 (1 ) 和中轴 (51 ) 两者为相同 的转动中心,传感器中运算放大器(28)的信号输出导线与电动自行车的电机控制器(29) 的信号输入端连接。 The connection relationship between the sensor and the electric bicycle is: the annular groove rotating disk (1) and the annular groove fixed disk (40) of the sensor are placed outside the central axis (51) of the electric bicycle, and the annular groove fixed disk (40) Fixedly connected to the casing (52) outside the central axis (51), the annular groove rotating disk (1) of the sensor is fixedly connected to the central axis (51) of the electric bicycle, and the annular grooved rotating disk (1) accompanies the central axis (51) 51) Synchronous rotation; the annular groove rotating disk (1) and the annular groove fixed disk (40) are nested inside and outside to form a rotational connection; the annular groove rotating disk (1) and the central axis (51) are the same The rotation center, the signal output wire of the operational amplifier (28) in the sensor is connected to the signal input end of the motor controller (29) of the electric bicycle.
2、 根据权利要求 1所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 还包括热敏电阻 R6, 热敏电阻 R6连接在运算放大器 (28) 的输入端和输出端 之间。 2. The power-assisted bicycle using a multi-magnetic block unevenly distributed magnetic flux sensor in the housing according to claim 1, characterized in that: it further includes a thermistor R6, and the thermistor R6 is connected to the input end of the operational amplifier (28) and between the output terminals.
3、 根据权利要求 2所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 助力模型处理器 (21 ) 是单片机 (31 ), 单片机 (31 ) 上连接有时钟电路 (32); 传感器的机械部件与传感部件结构关系:传感器的机械部件包括环形凹槽转动盘(1 ) 和相嵌合的环形凹槽固定盘 (40), 传感器的传感部件包括多个永磁块 (2)、 霍尔 (3 )、 单片机 (31 )、 数模转换器 (27) 和运算放大器 (28); 传感部件中依次相连的霍尔 (3 )、 单片机(31 )、 数模转换器(27)和运算放大器(28) 四个电子元件设在一块电路板(59) 上; 在空心环 (41 ) 的环形凹槽转动盘 (1 ) 内壁固定多个永磁块 (2), 在空心环 (41 ) 的环形凹槽固定盘(40) 内壁固定电路板(59), 电路板(59)上的霍尔 (3 )设在能感受 永磁块 (2) 的磁通量, 并且霍尔 (3 ) 能根据磁通量变化输出变化电信号的位置。 3. The power-assisted bicycle using unevenly distributed magnetic flux sensors with multiple magnet blocks in the casing according to claim 2, characterized in that: the power-assisted model processor (21) is a single-chip microcomputer (31), and a clock is connected to the single-chip microcomputer (31). Circuit (32); Structural relationship between the mechanical components of the sensor and the sensing components: the mechanical components of the sensor include an annular groove rotating disk (1) and a fitted annular groove fixed disk (40), and the sensing components of the sensor include multiple permanent magnet blocks (2), Hall (3), Microcontroller (31), digital-to-analog converter (27) and operational amplifier (28); Hall (3), microcontroller (31), digital-to-analog converter (27) and operational amplifier (28) connected in sequence in the sensing component Four electronic components are arranged on a circuit board (59); a plurality of permanent magnet blocks (2) are fixed on the inner wall of the annular groove of the hollow ring (41) and the rotating disk (1). The circuit board (59) is fixed on the inner wall of the fixed plate (40). The Hall (3) on the circuit board (59) is set to be able to sense the magnetic flux of the permanent magnet block (2), and the Hall (3) can output changes according to changes in the magnetic flux. location of electrical signals.
4、 根据权利要求 3所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 霍尔 (3 ) 是 UGN3075, 助力模型处理器 (21 ) 是 AT89S52单片机 (31 ), 数模 转换器 (27) 是 ADC-C8E; 运算放大器 (28) 是 OF-17F, OF-17F运算放大器 (28) 的 输入端 2脚与输出端 6脚之间连接有热敏电阻 R6; 各部件连接关系如下: 4. The power-assisted bicycle using unevenly distributed magnetic flux sensors with multiple magnet blocks in the casing according to claim 3, characterized in that: the Hall (3) is UGN3075, and the power-assisted model processor (21) is an AT89S52 single-chip microcomputer (31) , the digital-to-analog converter (27) is ADC-C8E; the operational amplifier (28) is OF-17F, and the thermistor R6 is connected between the input pin 2 and the output pin 6 of the OF-17F operational amplifier (28); The connection relationship of each component is as follows:
霍尔 (3 ) 的信号输出端 3脚连接单片机 (31 ) 的 12脚 INTO [P32]; The signal output terminal 3 of the Hall (3) is connected to the 12-pin INTO [P32] of the microcontroller (31) ;
单片机 (31 ) 的 39脚 P00连接数模转换器 (27) 的 12脚 B8; The 39-pin P00 of the microcontroller (31) is connected to the 12-pin B8 of the digital-to-analog converter (27);
单片机 (31 ) 的 38脚 P01连接数模转换器 (27) 的 11脚 B7; The 38-pin P01 of the microcontroller (31) is connected to the 11-pin B7 of the digital-to-analog converter (27);
单片机 (31 ) 的 37脚 P02连接数模转换器 (27) 的 10脚 B6; The 37-pin P02 of the microcontroller (31) is connected to the 10-pin B6 of the digital-to-analog converter (27);
单片机 (31 ) 的 36脚 P03连接数模转换器 (27) 的 9脚 B5; The 36-pin P03 of the microcontroller (31) is connected to the 9-pin B5 of the digital-to-analog converter (27);
单片机 (31 ) 的 35脚 P04连接数模转换器 (27) 的 8脚 B4; The 35-pin P04 of the microcontroller (31) is connected to the 8-pin B4 of the digital-to-analog converter (27);
单片机 (31 ) 的 34脚 P05连接数模转换器 (27) 的 7脚 B3; The 34-pin P05 of the microcontroller (31) is connected to the 7-pin B3 of the digital-to-analog converter (27);
单片机 (31 ) 的 33脚 P06连接数模转换器 (27) 的 6脚 B2; The 33-pin P06 of the microcontroller (31) is connected to the 6-pin B2 of the digital-to-analog converter (27);
单片机 (31 ) 的 32脚 P07连接数模转换器 (27) 的 5脚 B1 ; The 32-pin P07 of the microcontroller (31) is connected to the 5-pin B1 of the digital-to-analog converter (27);
数模转换器 (27) 的 4脚连接运算放大器 (28) 的 2脚; Pin 4 of the digital-to-analog converter (27) is connected to pin 2 of the operational amplifier (28);
数模转换器 (27) 的 2脚连接运算放大器 (28) 的 3脚; Pin 2 of the digital-to-analog converter (27) is connected to pin 3 of the operational amplifier (28);
运算放大器 (28) 的 6脚为模拟信号输出端。 Pin 6 of the operational amplifier (28) is the analog signal output.
5、 根据权利要求 1-4任何一项所述的用壳体内多磁块不均勾分布磁通量传感器的助力自 行车, 其特征在于: 环形凹槽固定盘 (40) 内圈的外表面与环形凹槽转动盘 (1 ) 内圈的 内表面之间设有轴承 (42)。 5. The power-assisted bicycle using unevenly distributed magnetic flux sensors with multiple magnet blocks in the housing according to any one of claims 1 to 4, characterized in that: the outer surface of the inner ring of the annular groove fixed plate (40) is in contact with the annular concave There are bearings (42) between the inner surfaces of the grooved rotating disk (1) and the inner ring.
6、 根据权利要求 5所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 传感器的环形凹槽固定盘 (40) 外表面设有圆形凹陷 (58); 圆形凹陷 (58) 与 电动自行车中轴 (51 )外的套管 (52)卡接, 成套管 (52)卡套在圆形凹陷 (58) 内固定 连接的结构。 6. The power-assisted bicycle using a multi-magnetic block unevenly distributed magnetic flux sensor in the housing according to claim 5, characterized in that: the outer surface of the annular groove fixed plate (40) of the sensor is provided with a circular depression (58); The circular depression (58) is clamped with the sleeve (52) outside the central axis (51) of the electric bicycle, and the sleeve (52) is clamped in the circular depression (58) and is fixedly connected to the structure.
7、 根据权利要求 5所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 霍尔 (3 ) 设在内圆形轨迹线与外圆形轨迹线之间。 7. The power-assisted bicycle using unevenly distributed magnetic flux sensors with multiple magnet blocks in the housing according to claim 5, characterized in that: the Hall (3) is located between the inner circular trajectory line and the outer circular trajectory line.
8、 根据权利要求 7所述的用壳体内多磁块不均勾分布磁通量传感器的助力自行车, 其特 征在于: 环形凹槽转动盘(1 )在多个永磁块(2) 的内圆形轨迹线所在圆范围内设有中心 孔。 8. The power-assisted bicycle using a multi-magnetic block unevenly distributed magnetic flux sensor in the housing according to claim 7, which is characterized by The characteristics are: the annular groove rotating disk (1) is provided with a central hole within the circle where the inner circular trajectory lines of the plurality of permanent magnet blocks (2) are located.
9、 根据权利要求 8所述的用壳体内多磁块不均匀分布磁通量传感器的助力自行车, 其特 征在于: 至少有一枚永磁块 (2) 的磁通量不等于其它任何一枚永磁块 (2) 的磁通量。 9. The power-assisted bicycle using a multi-magnetic block unevenly distributed magnetic flux sensor in the casing according to claim 8, characterized in that: the magnetic flux of at least one permanent magnet block (2) is not equal to that of any other permanent magnet block (2) ) of magnetic flux.
10、根据权利要求 9所述的用壳体内多磁块不均匀分布磁通量传感器的助力自行车,其特 征在于: 环形凹槽转动盘 (1 ) 是不导磁材料的塑料板、 铝材板、 铜材板的某一种。 10. The power-assisted bicycle using a multi-magnetic block unevenly distributed magnetic flux sensor in the casing according to claim 9, characterized in that: the annular groove rotating disk (1) is made of non-magnetic material: plastic plate, aluminum plate, copper A type of wood board.
PCT/CN2013/076819 2012-07-28 2013-06-05 Power-assist bicycle using sensor having multiple magnetic blocks of unevenly distributed magnetic fluxes in housing WO2014019412A1 (en)

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