CN209258419U - Whole static balance of unmanned aerial vehicle rotor and one-way dynamic balance test system - Google Patents
Whole static balance of unmanned aerial vehicle rotor and one-way dynamic balance test system Download PDFInfo
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- CN209258419U CN209258419U CN201822078604.4U CN201822078604U CN209258419U CN 209258419 U CN209258419 U CN 209258419U CN 201822078604 U CN201822078604 U CN 201822078604U CN 209258419 U CN209258419 U CN 209258419U
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Abstract
The utility model provides a whole static balance of unmanned aerial vehicle rotor and one-way dynamic balance test system belongs to unmanned air vehicle technical field, contains: the rotor wing rotor comprises a frame base part, a total distance adjusting part, a rotor wing driving part, a static balance detecting part, a dynamic balance detecting part and an acquisition recording part; the frame base part fixes the system on the ground; the total distance adjusting part is used for adjusting the tension of the rotor wing; the rotor driving part is used for driving the rotor to rotate at a high speed; the static balance detection part is used for detecting the centrifugal force of the rotor hub-rotor blade on the rotor shaft to obtain the integral static balance characteristic; the dynamic balance detection part is used for detecting the alternating aerodynamic moment of the rotor blade to the rotor shaft; the acquisition and recording part is used for acquiring and processing static balance and dynamic balance data of the rotor wing in real time and recording the data in the data recorder. The system can accurately detect and record the integral static balance characteristic of the rotor hub and the rotor blade in real time and the unidirectional dynamic balance characteristic of the rotor tension, so that the rotor system can be adjusted pertinently, and the integral static balance and dynamic balance are realized.
Description
Technical field
The utility model relates to a kind of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance, for detecting nothing
Man-machine rotor blade dynamic balancing can detect the dynamic balance property of rotor blade in accurate actual time safety.It is mainly used in navigating
The technical fields such as empty space flight and unmanned plane.
Background technique
The imbalance of rotor is that the principal vibration of the rotors class vertically taking off and landing flyer such as helicopter, multi-rotor aerocraft comes
Source.Rotor is usually made of multi-disc blade, and there may be certain differences for the centrifugal force and aerodynamic force of every blade.In rotor height
Speed rotation in the case where, the above-mentioned gentle power difference of centrifugal force can to rotor shaft generate alternating load, show as static unbalance and
Unbalance dynamic.Static unbalance and unbalance dynamic phenomenon not only cause vibration and the noise of aircraft, and can reduce flying quality,
Handling quality and service life.To eliminate above-mentioned phenomenon, it is necessary to carry out the static balance and dynamic balance analysis work of rotor.
Current static balance analysis is in a static condition, to weigh and the work of the check weighing heart for what blade carried out mostly.
Due to being influenced by measuring device and mode, above-mentioned static balance analysis precision is limited, and can not really reflect the rotation of rotor
Turn working condition.In addition, rotor hub is also possible to, there are static unbalance.In the case, though blade in a static condition
Reach balance, still can lead to whole static unbalance due in the rotor hub for being mounted on static unbalance.
Current dynamic balance analysis is under conditions of rotor blade high speed rotation, by the fortune for measuring rotor blade tip mostly
Dynamic rail mark, and then detect the dynamic balancing of rotor.Since blade tip motion profile is aerodynamic force, centrifugal force suffered by blade, gravity, and
The many factors such as blade amount of deflection are coefficient as a result, therefore blade tip flatness of the response is not fully the direct of blade aerodynamic power
Reflection.
Utility model content
The technical problem to be solved by the utility model is in order to overcome the shortcomings in the prior art, the utility model mentions
For a kind of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance.
The utility model solves its technical problem technical solution to be taken: a kind of unmanned plane rotor entirety static balance
And unidirectional Test System of Dynamic Balance, contain: framework bottom portions, always away from adjustment section, rotor driving portion, static balance test section, dynamic flat
Weigh test section and acquisition and recording portion, in which:
Framework bottom portions, contain: top panel, lower panel, and the branch to play a supportive role between upper and lower two pieces of panels
Dagger component;The lower panel contains fixed device, for whole system to be securely fixed in ground;
Always away from adjustment section, contain: steering engine mounting base, steering engine, always away from rocker arm, support base, always away from sliding block and pitch-change-link;
Described steering engine one end is mounted on the top panel in a manner of being fixedly connected or being rotatablely connected by steering engine mounting base, another
It holds and is always rotatablely connected away from rocker arm;The steering engine can deflection angle or change length, with drive always away from rocker arm deflect;It is described total
Away from the rocker arm other end with always connect away from sliding block, the support base upper end and described always away from being rotatablely connected in the middle part of rocker arm, and junction
Fulcrum is formed, the support base lower end is connected on top panel, is used to support always away from rocker arm;Lever principle always is used away from rocker arm,
Fulcrum and support base are rotatablely connected, and one end and the steering engine are rotatablely connected, the other end with always connect away from sliding block;Always supported away from rocker arm
Seat is used to support fulcrum always away from rocker arm;Described always includes rocker arm ontology away from rocker arm, and rocker arm ontology one end is equipped with for connecting
The first U-shaped arm of steering engine is connect, the other end is equipped with for connecting the second U-shaped arm always away from sliding block, and the steering engine upper end is located at the first U
On the inside of arm, and it is rotatablely connected by shaft and the first U-shaped arm, it is described to be always located on the inside of the second U-shaped arm away from sliding block, and by turning
Axis and the second U-shaped arm are rotatablely connected.Always divide upper and lower part two parts away from sliding block, and is rotatablely connected by bearing;Wherein, lower part
Do not rotated around rotor shaft, lower part with always connect away from rocker arm, and can be slided up and down along rotor shaft;Top and rotor shaft synchronous rotary,
Top is successively connect with pitch-change-link and rotor hub, the propeller pitch angle for synchronous change rotor blade.The support base includes
Supporting block and support arm, the supporting block lower end are connect with top panel, and upper end connects two support arms being oppositely arranged, two branch
The front and back side of supporting block between brace is equipped with evacuation inclined-plane.The supporting block and support arm integrally connected.
Rotor driving portion, contains: driving motor, shaft coupling, rotor shaft, pulling force positioning shaft sleeve, centrifugal force axle sleeve and rotation
Wing propeller hub;The driving motor bottom surface is fixed on lower panel, and the output shaft of driving motor connects rotor shaft by shaft coupling
One end, and the rotor shaft is allowed to generate a degree of angular variation and axial dipole field;The rotor shaft other end sequentially passes through
After the pulling force positioning shaft sleeve and centrifugal force axle sleeve, it is connected with the rotor hub, the rotor hub upper end connects rotor
Leaf;For the pulling force positioning shaft sleeve by internal bearing and rotor axis connection, the pulling force positioning shaft sleeve can be in rotor shaft
The axial position being kept fixed, and bear the pulling force of rotor hub;Connected inside the centrifugal force axle sleeve by bearing and rotor shaft
It connects, and is able to bear the centrifugal force of rotor shaft, connect outside the centrifugal force axle sleeve with static balance sensor base.
Static balance test section, contains: angular displacement sensor, static balance strain gauge group and static balance sensor base;
The angular displacement sensor is arranged in rotor shaft, and the angular displacement sensor is for detecting the rotor hub
Azimuth ψ and angular velocity omega, calculation formula are as follows:
ω=f (Δ ψ/Δ T),
Wherein, ω by the angular displacement sensor in each sampling period Δ T, the side of the rotor hub detected
The variation delta ψ of parallactic angle is calculated, and f is the filtering algorithm used, including but not limited to first-order filtering, second-order filter, smooth
Filtering, IIR filtering etc.;And have:
The static balance strain gauge group is divided between the static balance sensor base and the top panel by multiple
The static balance strain gauge composition of cloth arrangement, for detecting the centrifugal force axle sleeve to the horizontal stress of the top panel;It is quiet
Equilibrium stress sensor at least 1, and a variety of distribution modes can be used;The installation position angle of each static balance strain gauge
For Ψs=[Ψs1,Ψs2,...,ΨsN]T, the distance away from rotor shaft axle center is rs=[rs1,rs2,...,rsN]T, examined in moment t
The horizontal force F of surveys(t)=[Fs1(t),Fs2(t),...,FsN(t)]T, wherein N is static balance strain gauge number;Static balance
Strain gauge is more, and measurement accuracy is higher.
Static balance sensor base is mounted on the outside of centrifugal force axle sleeve, and top panel is set in static balance sensor base
Outside, static balance strain gauge group are arranged above between plate and static balance sensor base.Static balance sensor bottom
Circumferentially arranged with the first stress plane identical with the static balance strain gauge quantity, the top panel on the lateral wall of seat
Mounting hole for installing static balance sensor base is equipped with, circumferentially arranged with described the on the inner sidewall of the mounting hole
One-to-one second stress plane of one stress plane, the static balance strain gauge setting are answered in the first stress plane and second
Between power face, and it is rigidly connected with the first stress plane and the second stress plane.
Dynamic balancing test section, contains: dynamic balancing strain gauge group and dynamic balancing sensor base;The dynamic balancing stress
Sensor group, the dynamic balancing stress sensing arranged by multiple horizontal distributions between dynamic balancing sensor base and the top panel
Device composition, for detecting the sensor base to the vertical pulling force of the top panel;Wherein, dynamic balancing strain gauge is at least
There is 1, and a variety of distribution modes can be used;The installation position angle of each dynamic balancing strain gauge is Ψd=[Ψd1,
Ψd2,...,ΨdN]T, the distance apart from rotor shaft axle center is rd=[rd1,rd2,...,rdN]T, what t was detected at any time hangs down
To power Fd(t)=[Fd1(t),Fd2(t),...,FdN(t)]T, wherein N is dynamic balancing strain gauge number;Dynamic balancing stress passes
Sensor is more, and measurement accuracy is higher.
The dynamic balancing sensor base is mounted on the outside of pulling force positioning shaft sleeve, and the lower section of plate located above;It is described dynamic
Balance sensor pedestal includes base body, and axle sleeve pulling force positioning shaft sleeve mounting hole, the bottom are equipped in the middle part of the base body
The outer rim of seat ontology is circumferentially arranged with multiple trailing arms extended outward, and the quantity of the trailing arm and dynamic balancing strain gauge
Quantity is identical, and the dynamic balancing strain gauge one-to-one correspondence is mounted on the trailing arm.
Acquisition and recording portion, containing data processing unit and data logger, the data processing unit and the balance are examined
Survey portion is connected, and passes for acquiring the static balance strain gauge group, dynamic balancing strain gauge group and the angular displacement in real time
The data of sensor;To obtain the data samples such as stress, azimuth and angular speed;The data processing unit is also remembered with the data
It records instrument to be connected, for the data sample to be recorded in real time in the data logger, is used for off-line analysis;At the data
Reason unit can also be connected with host computer, by the data sample real-time Transmission to host computer, be used for on-line analysis.
In the case where rotor hub and rotor blade static balance, the centrifugation of high-speed rotating rotor hub and rotor blade
Power is cancelled out each other, and the stress of alternation will not be generated to the static balance sensor base;It is quiet not in rotor hub and rotor blade
In the case where balance, high-speed rotating rotor hub and rotor blade can generate centrifugal force in the horizontal direction, and successively act on
In the rotor shaft, the rotor axle sleeve and static balance sensor base;The static balance strain gauge group, passes through static balance
Sensor detects the rotor shaft and covers upper stress, and stress T suffered by real-time rotor hub can be obtainedhubWith azimuth ψhubNumber
According to calculation formula are as follows:
Wherein, T and ψTThe amplitude of respectively described the detected resultant force of static balance strain gauge group and azimuth, TyAnd Tx
Component of the respectively described resultant force T along x-axis and y-axis, FiAnd ψiThe stress and peace of respectively each static balance strain gauge detection
Fill azimuth, K1For proportionality coefficient.
In the dynamically balanced situation of rotor blade, the conjunction aerodynamic moment between high-speed rotating rotor blade goes to zero, no
The power and torque of alternation can be generated to the rotor shaft, pulling force positioning shaft sleeve and dynamic balancing sensor base;It is dynamic in rotor blade
In unbalanced situation, conjunction aerodynamic moment can be generated between high-speed rotating rotor blade, and then fixed to the rotor shaft, pulling force
Position axle sleeve and dynamic balancing sensor base generate the power and torque of alternation;The dynamic balancing strain gauge group passes through described in detection
The conjunction aerodynamic moment mean value of rotor hub is calculated in alternate stress in dynamic balancing sensor base are as follows:
Wherein, Fi maxAnd Fi minRespectively dynamic balancing strain gauge i=1 ..., the maximum stress and minimum that N is detected
Stress;Due to rotor hinge aerodynamic moment MhubWith aerodynamic moment MiRotor blade bigger than normal is corresponding, and MiWith Fi maxIt is corresponding;Cause
This is according to Mhub、Fi maxWith azimuth ψA(t) corresponding relationship can determine aerodynamic moment MiRotor blade bigger than normal, so as to
Targetedly to carry out the work of rotor blade dynamic balancing adjustment.
The action process of test macro:
Driving motor drives rotor shaft rotation, so that rotor hub and rotor blade be made to rotate synchronously, leads in rotation process
Cross steering engine adjustment rotor blade azimuth, when steering engine moves down, steering engine drive always away from rocker arm around fulcrum rotate, make always away from
The rocker arm other end rises, to make always away from sliding block along rotor shaft upward sliding, while pitch-change-link being driven to move upwards and simultaneously
Rotor hub is pushed to deflect around its pitch hinge, so that the propeller pitch angle of rotor blade and corresponding aerodynamic force be made to increase;When steering engine to
When upper mobile, steering engine drive is always rotated backward away from rocker arm around fulcrum, is made always away from dropping on the rocker arm other end, to make always away from sliding block edge
Rotor glides downward, while driving pitch-change-link to move downward and rotor hub is pushed to deflect around its pitch hinge simultaneously, thus
The propeller pitch angle and corresponding aerodynamic force for making rotor blade reduce.
In the case where rotor hub and rotor blade static unbalance, high-speed rotating rotor hub and rotor blade can be
Horizontal direction generates centrifugal force, and successively acts in the rotor shaft, the rotor axle sleeve and static balance sensor base;Institute
Static balance strain gauge group is stated, the rotor shaft is detected by static balance sensor and covers upper stress, to detect rotor
The static balance characteristic of hub and rotor blade.
In the case where rotor blade unbalance dynamic, conjunction aerodynamic moment can be generated between high-speed rotating rotor blade, into
And the power and torque of alternation are successively generated to the rotor shaft, pulling force positioning shaft sleeve and dynamic balancing sensor base;It is described dynamic flat
The strain gauge group that weighs is by detecting the alternate stress in the dynamic balancing sensor base, to detect the dynamic flat of rotor blade
Weigh characteristic.
Unmanned plane rotor entirety static balance and the test of unidirectional Test System of Dynamic Balance and Optimizing Flow are as follows:
1) a piece of rotor blade is selected as baseline blade A, and in moment t, the azimuth of baseline blade A is ψA(t);
2) rotor blade is not installed, rotor hub and rotor blade are accelerated to rated speed, led to by the starting of rotor driving portion
It crosses static balance strain gauge and detects stress on the centrifugal force axle sleeve, obtain stress T suffered by real-time rotor hubhubWith
Azimuth ψhubData;
3) according to Thub、ψhubWith ψA(t) corresponding relationship determines and adjusts the static balance characteristic of rotor hub, repeatedly weight
Retrial is tested, until ThubVariable quantity reach design requirement, realize the static balance of rotor hub;
4) rotor blade is installed, rotor hub and rotor blade are accelerated to rated speed, passed through by the starting of rotor driving portion
Static balance strain gauge detects the stress on the centrifugal force axle sleeve, obtains stress T suffered by real-time rotor hubhubThe side and
Parallactic angle ψhubData;
5) according to Thub、ψhubWith ψA(t) corresponding relationship determines and adjusts the static balance characteristic of rotor blade, repeatedly weight
Retrial is tested, until ThubVariable quantity reach design requirement, realize the whole static balance of rotor hub and rotor blade;
6) install rotor blade, rotor driving portion starting, rotor hub and rotor blade are accelerated into rated speed, always away from
Adjustment section starting, by always away from being adjusted in scope of design, and according to design requirement appropriate adjustment, to any strain gauge i=
1 ..., N records its maximum stress Fi max, minimum stress Fi minWith ψA(t) corresponding relationship;
7) M is calculatedhub, according to Mhub、Fi maxWith azimuth ψA(t) corresponding relationship determines and adjusts aerodynamic moment MiIt is bigger than normal
Rotor blade, be repeated several times test, until MhubVariable quantity reach design requirement, realize rotor blade dynamic balancing;
8) the whole static balance of rotor hub and rotor blade and the adjustment of unidirectional dynamic balancing measurement terminate.
The alternate stress born by analysis centrifugal force snesor pedestal, and pair with azimuth, angular speed and time
It should be related to, can detect rotor hub and rotor hub-rotor blade centrifugal force difference;Obtain rotor hub and rotor
The static balance of leaf quantifies detection data, so as to targetedly adjust related rotor hub and rotor blade, realizes whole
Static balance.
The alternate stress born by analysis tension sensor pedestal, and it is corresponding with azimuth, angular speed and time
Relationship can detect the aerodynamic moment difference between different rotor blades;The dynamic balancing quantization detection data of rotor blade is obtained, from
And it can targetedly adjust related rotor blade.
The beneficial effects of the utility model are: a kind of unmanned plane rotor entirety static balance provided by the utility model and unidirectional
Test System of Dynamic Balance can accurately detect rotor hub in horizontal plane by using static balance strain gauge group in real time
Interior centrifugal stress;By using dynamic balancing strain gauge group, each rotor blade aerodynamic power can be accurately detected in real time
Difference;By using always away from adjustment section, the aerodynamic force size of rotor blade can be adjusted in real time;By using angle displacement transducer
Device can accurately detect azimuth and the angular speed of rotor blade in real time;By the centrifugal stress of comparative analysis rotor hub,
Azimuth and angular speed, static balance level and the rotor hub-rotor blade entirety that can accurately analyze rotor hub are quiet
Equilibrium level;By the aerodynamic force of each rotor blade of comparative analysis, azimuth and angular speed, rotor blade can be accurately analyzed
Dynamic balancing it is horizontal.Utility model has the advantages that measurement is accurate, simple, intuitive, real-time are good, it is suitble to rotor hub and rotation
The whole static balance of wing blade and rotor thrust dynamic balancing measurement and adjustment.
Detailed description of the invention
The utility model is described in further detail with reference to the accompanying drawings and examples.
Fig. 1 is the perspective view of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance.
Fig. 2 is the side view of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance.
Fig. 3 is the structural representation of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance (without rotor blade)
Figure.
Fig. 4 is the positional relationship top view of strain gauge group, sensor base and positioning shaft sleeve.
Fig. 5 is structural schematic diagram always away from rocker arm.
Fig. 6 is structural schematic diagram always away from sliding block.
Fig. 7 is the structural schematic diagram of support base.
Fig. 8 is the positional diagram of strain gauge group, sensor base and positioning shaft sleeve.
Fig. 9 is the schematic diagram for measuring rotor and closing aerodynamic moment (2 blade).
Figure 10 is the schematic diagram for measuring rotor and closing aerodynamic moment (3 blade).
Figure 11 is the system architecture diagram of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance.
Figure 12 is the typical test flow figure of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance.
In figure: 1a. top panel, 1b. support column assembly, 1c. lower panel, 2. driving motors, 3. shaft couplings, 4. rotor shafts,
5. pulling force positioning shaft sleeve, 6. dynamic balancing sensor bases, 7. dynamic balancing strain gauge groups, 701. dynamic balancing strain gauges,
702. dynamic balancing strain gauges, 703. dynamic balancing strain gauges, 704. dynamic balancing strain gauges, 8. angle displacement transducers
Device, 9. static balance strain gauge groups, 91. static balance sensor bases, 92. centrifugal force axle sleeves, 901. static balance stress sensings
Device, 902. static balance strain gauges, 903. static balance strain gauges, 904. static balance strain gauges, 10. data processings
Unit, 11. data loggers, 12. always away from sliding block, 1201. tops, 1202. lower parts, 1203. pull rod support arms, the drawing of 13. displacements
Bar, 14. rotor hubs, 15. rotor blades, 1601. steering engine mounting bases, 1602. steering engines, 1603. always away from rocker arm, 1603a. first
U-shaped arm, the U-shaped arm of 1603b. second, 1603c. rocker arm ontology, 1604. support bases, 1604a. supporting block, 1604b. support arm,
1604c. avoids inclined-plane, 18. lower margins, 19. fixation holes.
Specific embodiment
The utility model is described in detail presently in connection with attached drawing.This figure is simplified schematic diagram, only in a schematic way
Illustrate the basic structure of the utility model, therefore it only shows composition related with the utility model.
As Figure 1-Figure 4, a kind of unmanned plane rotor entirety static balance of the utility model and unidirectional dynamic balancing measurement system
System, containing framework bottom portions, always away from adjustment section, rotor driving portion, static balance test section, dynamic balancing test section and acquisition and recording
Portion, in which:
Framework bottom portions, contain: top panel 1a, lower panel 1c, and play a supportive role between upper and lower two pieces of panels
Support column assembly 1b;The lower panel 1c contains fixed device, for whole system to be securely fixed in ground;This reality
It applies and supports column assembly 1b using four columns in example, form distributed rectangular, also set on plate 1c below position corresponding with column
There is lower margin 18, lower margin 18 is equipped with the fixation hole 19 for connecting with ground.
Always away from adjustment section, contain: steering engine mounting base 1601, steering engine 1602, always away from rocker arm 1603, support base 1604, always away from
Sliding block 12 and pitch-change-link 13;It is installed in a manner of being fixedly connected or being rotatablely connected by steering engine described 1602 one end of steering engine
Seat 1601 is mounted on the top panel 1a, the other end be always rotatablely connected away from rocker arm 1603;The steering engine 1602 can deflect
Angle changes length, is always deflected away from rocker arm 1603 with driving;Always lever principle, fulcrum and support base are used away from rocker arm 1603
1604 rotation connections, one end and the steering engine 1602 are rotatablely connected, the other end with always connect away from sliding block 12;Support base 1604 is used for
Support the fulcrum always away from rocker arm 1603.
As shown in figure 5, described always includes rocker arm ontology 1603c away from rocker arm 1603, described one end rocker arm ontology 1603c is equipped with
The first U-shaped arm 1603a for connecting steering engine 1602, the other end are equipped with for connecting the second U-shaped arm always away from sliding block 12
1603b, 1602 upper end of steering engine are located on the inside of the first U-shaped arm 1603a, and are connected by shaft and the first U-shaped arm 1603a rotation
It connects, it is described to be always located on the inside of the second U-shaped arm 1603b away from sliding block 12, and be rotatablely connected by shaft and the second U-shaped arm 1603b.
As shown in fig. 6, always dividing top 1201 and lower part 1202 two parts away from sliding block 12, and it is rotatablely connected by bearing;Its
In, lower part 1202 is not rotated around rotor shaft 4, lower part 1202 with always connect away from rocker arm 1603, and can be slided up and down along rotor shaft 4;
Top 1201 and 4 synchronous rotary of rotor shaft, top 1201 successively connect with pitch-change-link 13 and rotor hub 14, changes for synchronizing
The propeller pitch angle of mutarotation wing blade 15;It is symmetrically arranged with two pairs of pull rod support arms 1203 on 1201 side wall of top, is rotatably supported in change
Bottom away from pull rod 13.
As shown in fig. 7, the support base 1604 includes supporting block 1604a and support arm 1604b, the supporting block 1604a
With support arm 1604b integrally connected, the lower end the supporting block 1604a is connect with top panel 1a, and upper end connects two and is oppositely arranged
Support arm 1604b, two support arm 1604b and supporting block 1604a form U-shaped mounting groove, the fulcrum always away from rocker arm 1603
In U-shaped mounting groove, evacuation inclined-plane 1604c, front and back are equipped with before and after the supporting block 1604a between two support arm 1604b
Evacuation inclined-plane 1604c makes supporting block 1604a form the wide trapezoidal or triangular-section in the narrow bottom in top, for always away from rocker arm 1603
It prevents from colliding when rotating around fulcrum.
Rotor driving portion, contains: driving motor 2, shaft coupling 3, rotor shaft 4, pulling force positioning shaft sleeve 5, centrifugal force axle sleeve 92
And rotor hub 14;The output shaft of the driving motor 2 connects rotor shaft 4 by shaft coupling 3, and allows the rotor shaft 4
Generate a degree of angular variation and axial dipole field;4 other end of rotor shaft sequentially pass through the pulling force positioning shaft sleeve 5 and from
After mental and physical efforts axle sleeve 92, it is connected with the rotor hub 14,14 upper end of rotor hub connects rotor blade 15;The pulling force locating shaft
Set 5 is connect by internal bearing with rotor shaft 4, the axial direction that the pulling force positioning shaft sleeve 5 can be kept fixed in rotor shaft 4
Position, and bear the pulling force of rotor hub 14;It is connect by bearing with rotor shaft 4 inside the centrifugal force axle sleeve 92, and can
The centrifugal force of rotor shaft 4 is born, 92 outside of centrifugal force axle sleeve is connect with static balance sensor base 91;The driving motor
2 bottom surface is connected with the lower panel 1c.
Static balance test section, contains: angular displacement sensor 8, static balance strain gauge group 9 and static balance sensor base
91;By rotating ring and not, rotating ring forms the angular displacement sensor 8, and rotating ring is connect with rotor shaft 4, not rotating ring and static balance sensor
Pedestal 91 connects;The angular displacement sensor 8 is used to detect the azimuth ψ and angular velocity omega of the rotor hub 14, calculates public
Formula are as follows:
ω=f (Δ ψ/Δ T),
Wherein, ω by the angular displacement sensor 8 in each sampling period Δ T, the rotor hub 14 that detects
Azimuthal variation delta ψ be calculated, f be use filtering algorithm, including but not limited to first-order filtering, second-order filter,
Smothing filtering, IIR filtering etc.;And have:
The static balance strain gauge group 9, by multiple in the static balance sensor base 91 and top panel 1a
Between static balance strain gauge 901,902,903,904 arranged evenly form, it is right for detecting the centrifugal force axle sleeve 92
The horizontal stress of the top panel 1a;Static balance strain gauge at least 1, and a variety of distribution modes can be used;It is each quiet
The installation position angle of equilibrium stress sensor 901,902,903,904 is Ψs=[Ψs1,Ψs2,...,ΨsN]T, away from rotor shaft 4
The distance in axle center is rs=[rs1,rs2,...,rsN]T, in the horizontal force F of moment t detections(t)=[Fs1(t),Fs2(t),...,
FsN(t)]T, wherein N is static balance strain gauge number;Static balance strain gauge is more, and measurement accuracy is higher.
Static balance sensor base 91 is mounted on the outside of centrifugal force axle sleeve 92, and top panel 1a is set in static balance sensing
91 outside of device pedestal, static balance strain gauge group 9 are arranged above between plate 1a and static balance sensor base 91.It is described quiet
Circumferentially arranged with the first stress identical with the static balance strain gauge quantity on the lateral wall of balance sensor pedestal 91
Plane, the top panel 1a are equipped with the mounting hole for installing static balance sensor base 91, the inner sidewall of the mounting hole
On circumferentially arranged with one-to-one second stress plane of first stress plane, static balance strain gauge setting exists
Between first stress plane and the second stress plane, and it is rigidly connected with the first stress plane and the second stress plane.
Dynamic balancing test section, contains: dynamic balancing strain gauge group 7 and dynamic balancing sensor base 6;The dynamic balancing is answered
Force snesor group 7 is answered by the dynamic balancing that multiple horizontal distributions between dynamic balancing sensor base 6 and the top panel 1a arrange
Force snesor 701,702,703,704 forms, for detecting the sensor base to the vertical pulling force of the top panel 1a;Its
In, dynamic balancing strain gauge at least 1, and a variety of distribution modes can be used;Each dynamic balancing strain gauge 701,
702,703,704 installation position angle is Ψd=[Ψd1,Ψd2,...,ΨdN]T, the distance apart from 4 axle center of rotor shaft is rd=
[rd1,rd2,...,rdN]T, the vertical force F of t detection at any timed(t)=[Fd1(t),Fd2(t),...,FdN(t)]T, wherein
N is dynamic balancing strain gauge number;Dynamic balancing strain gauge is more, and measurement accuracy is higher.
As shown in figure 8, the dynamic balancing sensor base 6 is mounted on 5 outside of pulling force positioning shaft sleeve, and plate 1a located above
Lower section;The dynamic balancing sensor base 6 includes base body, is equipped with pulling force positioning shaft sleeve 5 in the middle part of the base body and pacifies
Hole is filled, the outer rim of the base body is circumferentially arranged with multiple trailing arms extended outward, and the quantity of the trailing arm is put down with dynamic
The strain gauge quantity that weighs is identical, and the dynamic balancing strain gauge one-to-one correspondence is mounted on the trailing arm.
As shown in figure 9, acquisition and recording portion, containing data processing unit 10 and data logger 11, the data processing list
Member 10 is connected with the balance detection portion, for acquiring the static balance strain gauge group 9, dynamic balancing strain gauge in real time
The data of group 7 and the angular displacement sensor 8;To obtain the data samples such as stress, azimuth and angular speed;The data processing
Unit 10 is also connected with the data logger 11, for the data sample to be recorded in real time at the data logger 11
In, it is used for off-line analysis;The data processing unit 10 can also be connected with host computer, and the data sample real-time Transmission is supreme
Position machine, is used for on-line analysis.
In the case where 15 static balance of rotor hub 14 and rotor blade, high-speed rotating rotor hub 14 and rotor blade
15 centrifugal force is cancelled out each other, and the stress of alternation will not be generated to the static balance sensor base 91;In 14 He of rotor hub
In the case where 15 static unbalance of rotor blade, high-speed rotating rotor hub 14 and rotor blade 15 can generate in the horizontal direction from
Mental and physical efforts, and act in the rotor shaft 4 and static balance sensor base 91;On centrifugal force axle sleeve 92;The static balance stress
Sensor group 9 detects described 4 sets of rotor shaft upper stress by static balance sensor, real-time 14 institute of rotor hub can be obtained
By stress ThubWith azimuth ψhubData, calculation formula are as follows:
Wherein, T and ψTThe respectively amplitude of the detected resultant force of the static balance strain gauge group 9 and azimuth, TyAnd Tx
Component of the respectively described resultant force T along x-axis and y-axis, FiAnd ψiRespectively each static balance strain gauge 901,902,903,
The stress of 904 detections and installation position angle, K1For proportionality coefficient.
In the dynamically balanced situation of rotor blade 15, the conjunction aerodynamic moment between high-speed rotating rotor blade 15 tends to
Zero, the power and torque of alternation will not be generated to the rotor shaft 4, pulling force positioning shaft sleeve 5 and dynamic balancing sensor base 6;It is revolving
In the case where 15 unbalance dynamic of wing blade, conjunction aerodynamic moment can be generated between high-speed rotating rotor blade 15, and then to described
Rotor shaft 4, pulling force positioning shaft sleeve 5 and dynamic balancing sensor base 6 generate the power and torque of alternation;The dynamic balancing stress sensing
The conjunction aerodynamic moment of rotor hub 14 is calculated by detecting the alternate stress in the dynamic balancing sensor base 6 in device group 7
Mean value are as follows:
Wherein, Fi maxAnd Fi minRespectively dynamic balancing strain gauge i=1 ..., the maximum stress and minimum that N is detected
Stress;Since rotor blade 15 closes aerodynamic moment MhubWith aerodynamic moment MiRotor blade 15 bigger than normal is corresponding, and MiWith Fi maxIt is right
It answers;Therefore according to Mhub、Fi maxWith azimuth ψA(t) corresponding relationship can determine aerodynamic moment MiRotor blade 15 bigger than normal,
So as to targetedly carry out the work of 15 dynamic balancing adjustment of rotor blade.
As shown in Figure 10-Figure 12, unmanned plane rotor entirety static balance and the test of unidirectional Test System of Dynamic Balance and optimization
Process are as follows:
1) it selectes a piece of rotor blade 15 and is used as baseline blade A, in moment t, the azimuth of baseline blade A is ψA(t);
2) rotor blade 15 is not installed, the starting of rotor driving portion accelerates to rotor hub 14 and rotor blade 15 specified
Revolving speed detects the stress on the centrifugal force axle sleeve 92 by static balance strain gauge 901,902,903,904, obtains in real time
Rotor hub 14 suffered by stress ThubWith azimuth ψhubData;
3) according to Thub、ψhubWith ψA(t) corresponding relationship determines and adjusts the static balance characteristic of rotor hub 14, repeatedly
It repeats to test, until ThubVariable quantity reach design requirement, realize the static balance of rotor hub 14;
4) rotor blade 15 is installed, rotor hub 14 and rotor blade 15 are accelerated to specified turn by the starting of rotor driving portion
Speed detects the stress on the centrifugal force axle sleeve 92 by static balance strain gauge 901,902,903,904, obtains in real time
Stress T suffered by rotor hub 14hubWith azimuth ψhubData;
5) according to Thub、ψhubWith ψA(t) corresponding relationship determines and adjusts the static balance characteristic of rotor blade 15, repeatedly
It repeats to test, until ThubVariable quantity reach design requirement, realize the whole static balance of rotor hub 14- rotor blade 15;
6) rotor blade 15 is installed, rotor hub 14 and rotor blade 15 are accelerated to specified turn by the starting of rotor driving portion
Speed always starts away from adjustment section, by always away from being adjusted in scope of design, and according to design requirement appropriate adjustment, passes to any stress
Sensor i=1 ..., N record its maximum stress Fi max, minimum stress Fi minWith ψA(t) corresponding relationship;
7) M is calculatedhub, according to Mhub、Fi maxWith azimuth ψA(t) corresponding relationship determines and adjusts aerodynamic moment MiIt is bigger than normal
Rotor blade 15, be repeated several times test, until MhubVariable quantity reach design requirement, realize 15 dynamic balancing of rotor blade;
8) the whole static balance of rotor hub 14 and rotor blade 15 and the adjustment of unidirectional dynamic balancing measurement terminate.
By analysis centrifugal force snesor pedestal 91 bear alternate stress, and with azimuth, angular speed and time
Corresponding relationship can detect the centrifugal force difference of rotor hub 14 and rotor hub 14 and rotor blade 15;Obtain rotor hub
The static balance of 14- rotor blade 15 quantifies detection data, so as to targetedly adjust related rotor hub 14 and rotor
Blade 15 realizes whole static balance.
The alternate stress born by analysis tension sensor pedestal 6, and it is corresponding with azimuth, angular speed and time
Relationship can detect the aerodynamic moment difference between different rotor blades 15;Obtain the dynamic balancing quantization testing number of rotor blade 15
According to realizing the dynamic balancing of rotor blade so as to targetedly adjust related rotor blade 15.
The utility model can accurately detect rotor hub 14 in real time and exist by using static balance strain gauge group 9
Centrifugal stress in horizontal plane;By using dynamic balancing strain gauge group 7, each rotor blade can be accurately detected in real time
The difference of 15 aerodynamic force;By using always away from adjustment section, the aerodynamic force size of rotor blade 15 can be adjusted in real time;By using angle
Displacement sensor 8 can accurately detect azimuth and the angular speed of rotor blade 15 in real time;Pass through comparative analysis rotor hub
14 centrifugal stress, azimuth and angular speed can accurately analyze the static balance level and rotor hub 14 of rotor hub 14
Whole static balance with rotor blade 15 is horizontal;Pass through the aerodynamic force of each rotor blade 15 of comparative analysis, azimuth and angle speed
Degree, the dynamic balancing that can accurately analyze rotor blade 15 are horizontal.Utility model has the advantages that measurement is accurate, simple, intuitive,
Real-time is good, is suitble to the whole static balance and rotor thrust dynamic balancing measurement and adjustment of rotor hub 14 and rotor blade 15.
It is enlightenment, through the above description, relevant work with the above-mentioned desirable embodiment according to the utility model
Personnel can carry out various changes and amendments in without departing from the scope of the utility model completely.This item utility model
Technical scope is not limited to the contents of the specification, it is necessary to which the technical scope thereof is determined according to the scope of the claim.
Claims (7)
1. a kind of unmanned plane rotor entirety static balance and unidirectional Test System of Dynamic Balance, it is characterised in that: contain: frame base
Portion, always away from adjustment section, rotor driving portion, static balance test section, dynamic balancing test section and acquisition and recording portion, in which:
Framework bottom portions, contain: the support to play a supportive role between top panel, lower panel and plate located above and lower panel
Column assembly;The lower panel contains fixed device, for fixing whole system;
Always away from adjustment section, contain: steering engine mounting base, steering engine, always away from rocker arm, support base, always away from sliding block and pitch-change-link;It is described
Steering engine one end is mounted on the top panel in a manner of being fixedly connected or being rotatablely connected by steering engine mounting base, the other end with
Always it is rotatablely connected away from rocker arm;It is described always away from the rocker arm other end with always connect away from sliding block, the support base upper end is with described always away from shaking
Rotation connection in the middle part of arm, and junction forms fulcrum;The support base lower end is connected on top panel, is used to support always away from shaking
Arm;Described always to divide upper and lower part two parts away from sliding block, upper and lower part is rotatablely connected by bearing;Wherein, lower part is not around rotation
The rotation of wing axis, and lower part with always connect away from rocker arm, and can be slided up and down along rotor shaft;Top and rotor shaft synchronous rotary, top
It is successively connect with pitch-change-link and rotor hub, the propeller pitch angle for synchronous change rotor blade;
Rotor driving portion, contains: driving motor, shaft coupling, rotor shaft, pulling force positioning shaft sleeve, centrifugal force axle sleeve and rotor
Hub;The driving motor bottom surface is fixed on lower panel, and the output shaft of driving motor connects rotor shaft one end by shaft coupling;
The rotor shaft other end sequentially passes through the pulling force positioning shaft sleeve and centrifugal force axle sleeve is connected with the rotor hub;The rotation
Wing propeller hub connects rotor blade;The pulling force positioning shaft sleeve passes through internal bearing and rotor axis connection, the pulling force locating shaft
The axial position that can be kept fixed in rotor shaft is covered, and bears the pulling force of rotor hub, outside the pulling force positioning shaft sleeve
It is connect with dynamic balancing sensor base;By bearing and rotor axis connection inside the centrifugal force axle sleeve, and it is able to bear rotor
The centrifugal force of axis, the centrifugal force axle sleeve outside are connect with static balance sensor base;
Static balance test section, contains: angular displacement sensor, static balance strain gauge group and static balance sensor base;It is described
Angular displacement sensor is arranged in rotor shaft, for detecting azimuth and the angular speed of the rotor hub;Static balance sensor
Pedestal is mounted on the outside of centrifugal force axle sleeve, and top panel is set on the outside of static balance sensor base;Static balance stress sensing
Device group is arranged above between plate and static balance sensor base, is answered for detecting centrifugal force axle sleeve the level of the top panel
Power;
Dynamic balancing test section, contains: dynamic balancing strain gauge group and dynamic balancing sensor base;Dynamic balancing sensor bottom
Seat is mounted on the outside of pulling force positioning shaft sleeve, and the lower section of plate located above;The dynamic balancing strain gauge group plate located above
It between dynamic balancing sensor base, and is mounted in dynamic balancing sensor base, for detecting dynamic balancing sensor base pair
The vertical pulling force of the top panel;
Acquisition and recording portion, contains: data processing unit and data logger;The data processing unit and the static balance detect
Portion is connected with dynamic balancing test section, for acquire in real time the static balance strain gauge group, dynamic balancing strain gauge group and
The data of angular displacement sensor, to obtain the data sample that stress, azimuth and angular speed are formed;The data processing unit is also
It is connected with the data logger, for the data sample to be recorded in real time in the data logger, for dividing offline
Analysis.
2. unmanned plane rotor entirety static balance as described in claim 1 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
Stating acquisition and recording portion further includes host computer, and the data processing unit is connected with host computer, by the data sample real-time Transmission
To host computer, it to be used for on-line analysis.
3. unmanned plane rotor entirety static balance as described in claim 1 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
It states static balance strain gauge group and contains at least one static balance strain gauge;The lateral wall of the static balance sensor base
On circumferentially arranged with the first stress plane identical with the static balance strain gauge quantity;The top panel is equipped with and is used for
The mounting hole of static balance sensor base is installed;On the inner sidewall of the mounting hole circumferentially arranged with first stress plane
One-to-one second stress plane;The static balance strain gauge is arranged between the first stress plane and the second stress plane,
And it is rigidly connected with the first stress plane and the second stress plane.
4. unmanned plane rotor entirety static balance as described in claim 1 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
Stating always includes rocker arm ontology away from rocker arm, and rocker arm ontology one end is equipped with the first U-shaped arm for connecting steering engine, and the other end is equipped with
For connecting the second U-shaped arm always away from sliding block;The steering engine upper end is located on the inside of the first U-shaped arm, and U-shaped by shaft and first
Arm rotation connection;It is described to be always located on the inside of the second U-shaped arm away from sliding block, and be rotatablely connected by shaft and the second U-shaped arm.
5. unmanned plane rotor entirety static balance as described in claim 1 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
It states dynamic balancing strain gauge group and contains at least one dynamic balancing strain gauge;The dynamic balancing sensor base includes pedestal
Ontology;Be equipped with axle sleeve pulling force positioning shaft sleeve mounting hole in the middle part of the base body, the outer rim of the base body circumferentially arranged with
Multiple trailing arms extended outward, and the quantity of the trailing arm is identical as dynamic balancing strain gauge quantity;The dynamic balancing is answered
Force snesor one-to-one correspondence is mounted on the trailing arm.
6. unmanned plane rotor entirety static balance as described in claim 1 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
Stating support base includes supporting block and support arm;The supporting block lower end is connect with top panel, what upper end connection two was oppositely arranged
The front and back side of support arm, the supporting block between two support arms is equipped with evacuation inclined-plane.
7. unmanned plane rotor entirety static balance as claimed in claim 6 and unidirectional Test System of Dynamic Balance, it is characterised in that: institute
State supporting block and support arm integrally connected.
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CN109502051A (en) * | 2018-12-12 | 2019-03-22 | 山东智翼航空科技有限公司 | Whole static balance of unmanned aerial vehicle rotor and one-way dynamic balance test system |
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CN109502051A (en) * | 2018-12-12 | 2019-03-22 | 山东智翼航空科技有限公司 | Whole static balance of unmanned aerial vehicle rotor and one-way dynamic balance test system |
CN109502051B (en) * | 2018-12-12 | 2024-04-02 | 山东智翼航空科技有限公司 | Unmanned aerial vehicle rotor overall static balance and unidirectional dynamic balance test system |
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