CN102092256A - Structure and method for reducing equivalent unsprung weight of wheel-rim electrically-driven system of single trailing arm type suspension - Google Patents
Structure and method for reducing equivalent unsprung weight of wheel-rim electrically-driven system of single trailing arm type suspension Download PDFInfo
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- CN102092256A CN102092256A CN 201110053092 CN201110053092A CN102092256A CN 102092256 A CN102092256 A CN 102092256A CN 201110053092 CN201110053092 CN 201110053092 CN 201110053092 A CN201110053092 A CN 201110053092A CN 102092256 A CN102092256 A CN 102092256A
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- unsprung weight
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Abstract
The invention discloses a structure and method for reducing the equivalent unsprung weight of a wheel electrically-driven system of a single trailing arm type suspension, which is characterized in that an elastic rubber hinge is supported on a frame, one end of a swing arm of the single trailing arm type suspension is connected with the elastic rubber hinge, and the other end of the swing arm is connected with a reducer casing; the reducer casing is connected with a sleeve of a half axle; a motor is fixedly arranged on the reducer casing, the power output end of the motor is connected with a small gear, then the small gear is meshed with the large gear, and the large gear is connected with the sleeve of the half axle; and after the gear reducing is performed, the power is outputted to a rim by the half axle so as to drive wheels. The equivalent unsprung weight is reduced by reducing the distance between the mass centre of non-concentric parts of a wheel and a central swing axis of the single trailing arm type suspension. The structure and method disclosed by the invention have the advantages of increasing the vibration frequencies of wheels, reducing the resonance, reducing the impact and vibration from road surfaces, and improving the running smoothness of vehicles.
Description
Technical field
The present invention relates to a kind of electric automobile chassis and transmission field, particularly a kind of single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure and method of reducing.
Background technology
Affects ride safety of automobile, the ride comfort of automobile unsprung weight (nonspring carried mass).At present, the wheel limit power drive system that with the electric drive wheel is representative is because its drive system and complete vehicle structure is succinct, driving efficiency is high, and each driving wheel torque can independently be controlled, and helps improving the rideability under the abominable pavement conditions and becomes the research focus.But, will increase the automobile unsprung weight because motor is installed in the drive wheel.
When calculating the automobile unsprung weight, the sole mass of all parts was as unsprung weight in directly will taking turns in the past.But this is devious in fact, and according to the form difference of suspension, the deviation of its generation is also with different.Particularly in the electronlmobil that uses the wheel limit to drive, because the wheel motor quality is bigger, its different arrangements with respect to suspension also will have bigger difference to the influence that automobile vibration produces.That is what, automobile vibration is really exerted an influence is equivalent unsprung weight.
Wheel limit power drive system mass distribution is not that wheel limit power drive system sole mass simple superposition is got final product, but should considers to take turns the distribution form of limit power drive system quality with respect to suspension the equivalent unsprung weight effect that automobile suspension system produced.
Summary of the invention
Technical matters to be solved by this invention is that a kind of unsprung weight that reduces will be provided, and that reduces resonance reduces single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure and method.
In order to solve above technical matters, the invention provides a kind of single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure that reduces, described single longitudenal arm suspension fork wheel edge power drive system comprises vehicle frame, the elastic caoutchouc hinge, the single longitudenal arm suspension swing arm, deceleration box, miniature gears, brake clamp, brake disc, hub bearing, semiaxis, wheel hub, wheel rim, motor, big gear wheel, axle tube, wherein elastic caoutchouc cuts with scissors, the single longitudenal arm suspension swing arm, deceleration box, axle tube and motor are fixedly installed in together, wheel hub, wheel rim, hub bearing, semiaxis, axle tube and brake disc are the parts concentric with wheel, deceleration box, miniature gears, brake clamp, motor and big gear wheel are and the nonconcentric(al) parts of wheel; Described elastic caoutchouc hinged bearing is in vehicle frame, one end and the elastic caoutchouc of single longitudenal arm suspension swing arm are hinged, and the other end is connected with deceleration box, and deceleration box is connected with axle tube, motor is installed on the deceleration box, be provided with power intake and clutch end in the deceleration box, the motor power mouth is connected with miniature gears, and miniature gears meshes with big gear wheel again, big gear wheel connects with axle tube, behind gear reduction, output power to wheel rim by semiaxis, with drive wheels.
To take turns the limit power drive system and be installed on the single longitudenal arm suspension, and swing around the single longitudenal arm center of oscillation.
Tradition vehicle body and vehicle frame coupled system model of vibration comprise body quality m
2, wheel mass m
1, suspension rate K, resistance of shock absorber coefficient C, tire stiffness K
t, input function of road surface roughness q.Select wheel and vehicle body vertical coordinate z
1, z
2Be generalized coordinate, the differential equation of motion that obtains system is:
Consider the coupled system model of vibration of the actual centroid position influence of suspension and vehicle wheel component, m
1Be suspension and vehicle wheel component quality, suppose that the actual centroid position of suspension and vehicle wheel component is L to the hinge length of swing arm and vehicle body
1, the swing arm length overall is L, the swing arm end with the vehicle body hinged place with the vehicle body bob,
For with respect to initial equipoise
Corner, J
1For suspension trailing arm and wheel limit power drive system pile warp are crossed self barycenter and are parallel to the rotor inertia of swing arm central axis.Suppose
,
For going up the initial deformation of lower spring under the static balance situation.
Introduce inertial force system, be converted into static problems.
Analyze the swing arm moment balance:
In addition according to having under the initial static balance situation:
In addition, the pass between three coordinates is:
Thereby (1), (2), (3) formula can be simplified to:
To (6) formula differentiate:
With (8) formula substitution (4) formula, cancellation
, with (4) formula substitution (5) formula cancellation
Can get set of equations:
The set of equations of more traditional coupled system model of vibration can obtain: equivalent unsprung weight
Simultaneously, can make the equivalence of wheel vertical stiffness be
By above analysis as seen, it only is that variation has taken place equivalent unsprung weight that model can be considered, promptly
As seen reduce equivalent unsprung weight and L
1With L certain relation is arranged.When single longitudenal arm suspension center of oscillation axis to wheel center length L one regularly, system's barycenter is the principal element that determines equivalent unsprung weight size to the distance size between the suspension center of oscillation axis.Here L
1The barycenter that is wheel and suspended rack assembly is to the distance between the single longitudenal arm suspension center of oscillation axis, so this centroid position affects L
1Size.
Certainly, this equivalent formula can be used for the calculating of the equivalent unsprung weight of single part generation, and both the equivalent unsprung weight of each parts can be considered
, for each part, its
Less, so the equivalent unsprung weight of each part is considered as
L wherein
iFor being numbered i(i=2,3 ..., 14) the part barycenter to the distance between the single longitudenal arm suspension center of oscillation axis.When part was calculated respectively, the centroid position when each part was more little to the distance between the single longitudenal arm suspension center of oscillation axis equally, and the equivalent unsprung weight of its generation is also just more little.
According to this formula, with equivalent unsprung weight separated into two parts, first comprises the parts concentric with wheel such as wheel rim, wheel hub, is immutable, and the equivalent unsprung weight of its generation can't change; Second portion is produced by the parts variable with respect to single longitudenal arm suspension center of oscillation axial line distance, this equivalence unsprung weight is directly proportional with sole mass, this ratio be its barycenter to suspension center of oscillation axial line distance than last wheel center to suspension center of oscillation axial line distance square, the equivalent unsprung weight of its generation is different and different with respect to the distance of single longitudenal arm with their barycenter, reasonable Arrangement is with respect to the parts of single longitudenal arm center of oscillation distance variable, reduce the distance of these parts barycenter, can reduce equivalent unsprung weight to single longitudenal arm suspension center of oscillation axis.
Superior effect of the present invention is:
1) reduces unsprung weight the unsteadiness of wheels frequency is improved, can reduce resonance, reduce, improve occupant's traveling comfort, improve ride of vehicle, improve the service life of parts from the ground-surface shock and vibration;
2) reduce the ground connection performance that unsprung weight can also better be suspended in midair dynamic response and improve wheel, increase the driving safety of automobile.
Description of drawings
Fig. 1 adopts the structural representation of single longitudenal arm suspension for the present invention;
Fig. 2 is traditional vehicle body and vehicle frame coupled system model of vibration figure;
Fig. 3 is for considering the coupled system model of vibration figure of the actual centroid position influence of suspension and vehicle wheel component;
Fig. 4 is the swing arm force diagram;
Fig. 5 is m
2Force analysis figure;
The number in the figure explanation
1-vehicle frame; 2-elastic caoutchouc hinge;
3-single longitudenal arm suspension swing arm; 4-deceleration box;
5-miniature gears; 6-brake clamp;
7-brake disc; 8-hub bearing;
9-semiaxis; 10-wheel hub;
12-motor; 13-big gear wheel;
14-axle tube.
The specific embodiment
See also shown in the accompanying drawing, the invention will be further described.
As shown in Figure 1, the invention provides a kind of single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure that reduces, described single longitudenal arm suspension fork wheel edge power drive system comprises vehicle frame 1, elastic caoutchouc hinge 2, single longitudenal arm suspension swing arm 3, deceleration box 4, miniature gears 5, brake clamp 6, brake disc 7, hub bearing 8, semiaxis 9, wheel hub 10, wheel rim 11, motor 12, big gear wheel 13, axle tube 14, wherein the elastic caoutchouc hinge 2, single longitudenal arm suspension swing arm 3, deceleration box 4, axle tube 14 and motor 12 are fixedly installed in together, wheel hub 10, wheel rim 11, hub bearing 8, semiaxis 9, axle tube 14 and brake disc 7 are parts concentric with wheel, deceleration box 4, miniature gears 5, brake clamp 6, motor 12 and big gear wheel 13 are and the nonconcentric(al) parts of wheel; Described elastic caoutchouc hinge 2 is supported on vehicle frame 1, one end of single longitudenal arm suspension swing arm 3 is connected with elastic caoutchouc hinge 2, the other end is connected with deceleration box 4, deceleration box 4 is connected with axle tube 14, motor 12 is installed on the deceleration box 4, be provided with power intake and clutch end in the deceleration box 4, motor 12 clutch ends are connected with miniature gears 5, miniature gears 5 meshes with big gear wheel 13 again, and big gear wheel 13 connects with axle tube 14, and hub bearing 8 is supported between axle tube 14 and the wheel hub 10, wheel hub 10 captive joint wheel rims 11, behind gear reduction, output power to wheel rim 11 by semiaxis 9, with drive wheels.Brake disc 7 is installed together with wheel rim 11, wheel hub 10, and together with wheel revolutions, and 6 of brake clamps are fixed on the axle tube 14 by the brake clamp adapter plate.
To take turns the limit power drive system and be installed on the single longitudenal arm suspension, and swing around the single longitudenal arm center of oscillation.
As shown in Figure 2, traditional vehicle body and vehicle frame coupled system model of vibration comprise body quality m
2, wheel mass m
1, suspension rate K, resistance of shock absorber coefficient C, tire stiffness K
t, input function of road surface roughness q.Select wheel and vehicle body vertical coordinate z
1, z
2Be generalized coordinate, the differential equation of motion that obtains system is:
As shown in Figure 3, consider the coupled system model of vibration of the actual centroid position influence of suspension and vehicle wheel component, m
1Be suspension and vehicle wheel component quality, suppose that the actual centroid position of suspension and vehicle wheel component is L to the hinge length of swing arm and vehicle body
1, the swing arm length overall is L, the swing arm end with the vehicle body hinged place with the vehicle body bob,
For with respect to initial equipoise
Corner, J
1For suspension trailing arm and wheel limit power drive system pile warp are crossed self barycenter and are parallel to the rotor inertia of swing arm central axis.Suppose
,
For going up the initial deformation of lower spring under the static balance situation.
Introduce inertial force system, be converted into static problems.
As shown in Figure 4, analyze the swing arm moment balance:
As shown in Figure 5, analyze
Stressed
In addition according to having under the initial static balance situation:
In addition, the pass between three coordinates is:
Thereby (1), (2), (3) formula can be simplified to:
To (6) formula differentiate:
With (8) formula substitution (4) formula, cancellation
, with (4) formula substitution (5) formula cancellation
Can get set of equations:
The set of equations of more traditional coupled system model of vibration can obtain: equivalent unsprung weight
Simultaneously, can make the equivalence of wheel vertical stiffness be
By above analysis as seen, it only is that variation has taken place equivalent unsprung weight that model can be considered, promptly
As seen reduce equivalent unsprung weight and L
1With L certain relation is arranged.When single longitudenal arm suspension center of oscillation axis to wheel center length L one regularly, system's barycenter is the principal element that determines equivalent unsprung weight size to the distance size between the suspension center of oscillation axis.Here L
1The barycenter that is wheel and suspended rack assembly is to the distance between the single longitudenal arm suspension center of oscillation axis, so this centroid position affects L
1Size.
Certainly, this equivalent formula can be used for the calculating of the equivalent unsprung weight of single part generation, and promptly the equivalent unsprung weight of each parts can be considered
, for each part, its
Less, so the equivalent unsprung weight of each part is considered as
L wherein
iFor being numbered i(i=2,3 ..., 14) the part barycenter to the distance between the single longitudenal arm suspension center of oscillation axis.When part was calculated respectively, the centroid position when each part was more little to the distance between the single longitudenal arm suspension center of oscillation axis equally, and the equivalent unsprung weight of its generation is also just more little.
According to this formula, with equivalent unsprung weight separated into two parts, first comprises the parts concentric with wheel such as wheel rim, wheel hub, is immutable, and the equivalent unsprung weight of its generation can't change; Second portion is produced by the parts variable with respect to single longitudenal arm suspension center of oscillation axial line distance, this equivalence unsprung weight is directly proportional with sole mass, this ratio be its barycenter to suspension center of oscillation axial line distance than last wheel center to suspension center of oscillation axial line distance square, the equivalent unsprung weight of its generation is different and different with respect to the distance of single longitudenal arm with their barycenter, reasonable Arrangement is with respect to the parts of single longitudenal arm center of oscillation distance variable, reduce the distance of these parts barycenter, can reduce equivalent unsprung weight to single longitudenal arm suspension center of oscillation axis.
Elastic caoutchouc hinge 2, single longitudenal arm suspension swing arm 3, deceleration box 4, miniature gears 5, brake clamp 6, brake disc 7, hub bearing 8, semiaxis 9, wheel hub 10, wheel rim 11, motor 12, big gear wheel 13, axle tube 14 among Fig. 1, centroid position be O, O to the distance between the single longitudenal arm suspension center of oscillation axis be L
1, the equivalent unsprung weight that these parts produced is
The equivalent unsprung weight of its generation of parts that wheel rim 11, wheel hub 10 etc. and wheel are concentric can't change, and its distance with respect to single longitudenal arm of parts such as motor 12, big gear wheel 13 is different and different according to arranging.With equivalent unsprung weight separated into two parts, first comprises that wheel rim 11, wheel hub 10 etc. are immutable, and second portion is that those parts with respect to single longitudenal arm axis of oscillation distance variable produce.According to shown in Figure 1, with motor 12, reduction pinion teeth 5, brake clamp 6, deceleration box 4, and big gear wheel 13 and the nonconcentric(al) parts of wheel, arrange to be close to single longitudenal arm center of oscillation axis, can effectively reduce the equivalent unsprung weight of system.
Single longitudenal arm suspension fork wheel edge power drive system can use coil spring, torsion bar spring.
Single longitudenal arm suspension fork wheel edge power drive system can be used for non-wheel flutter, the complete use in the left and right sides.
Claims (2)
1. one kind reduces single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure, it is characterized in that: described single longitudenal arm suspension fork wheel edge power drive system comprises vehicle frame, the elastic caoutchouc hinge, the single longitudenal arm suspension swing arm, deceleration box, miniature gears, brake clamp, brake disc, hub bearing, semiaxis, wheel hub, wheel rim, motor, big gear wheel, axle tube, wherein elastic caoutchouc cuts with scissors, the single longitudenal arm suspension swing arm, deceleration box, axle tube and motor are fixedly installed in together, wheel hub, wheel rim, hub bearing, semiaxis, axle tube and brake disc are the parts concentric with wheel, deceleration box, miniature gears, brake clamp, motor and big gear wheel are and the nonconcentric(al) parts of wheel; Described elastic caoutchouc hinged bearing is in vehicle frame, one end and the elastic caoutchouc of single longitudenal arm suspension swing arm are hinged, and the other end is connected with deceleration box, and deceleration box is connected with axle tube, motor is installed on the deceleration box, be provided with power intake and clutch end in the deceleration box, the motor power mouth is connected with miniature gears, and miniature gears meshes with big gear wheel again, big gear wheel connects with axle tube, behind gear reduction, output power to wheel rim by semiaxis, with drive wheels.
2. the method that reduces single longitudenal arm suspension fork wheel edge power drive system equivalence unsprung weight structure according to claim 1 is characterized in that: will take turns the limit power drive system and be installed on the single longitudenal arm suspension, and swing around the single longitudenal arm center of oscillation; With the nonconcentric(al) parts of wheel, be variable in the wheel limit power drive system, reduce the distance of these parts barycenter, promptly reduced equivalent unsprung weight to single longitudenal arm suspension center of oscillation axis with respect to the distance of single longitudenal arm suspension center of oscillation axis.
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102582417A (en) * | 2012-02-24 | 2012-07-18 | 无锡永凯达齿轮有限公司 | Speed-reducing type wheel electric drive system of electric vehicle |
CN103707749A (en) * | 2013-12-11 | 2014-04-09 | 同济大学 | Integrated single-trailing-arm gear-reducing type electric wheel drive system |
CN103832271A (en) * | 2014-02-27 | 2014-06-04 | 浙江工业大学之江学院工业研究院 | Independent drive independent steering mechanism of electric vehicle |
CN108313889A (en) * | 2018-01-03 | 2018-07-24 | 徐亚杰 | A kind of Super High creeping formwork auxiliary hoisting device |
CN110001381A (en) * | 2019-04-16 | 2019-07-12 | 智导灵(苏州)智能科技有限公司 | A kind of new-energy automobile wheel side separated type drive assembly |
CN111186269A (en) * | 2020-01-21 | 2020-05-22 | 同济大学 | Integrated symmetric support single-swing-arm suspension wheel side electric driving system |
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CN200953505Y (en) * | 2006-10-09 | 2007-09-26 | 上海燃料电池汽车动力系统有限公司 | Composite axle planetary frame outputting external rotor hub electric machine structure |
WO2008035455A1 (en) * | 2006-09-19 | 2008-03-27 | Ntn Corporation | Sensor-equipped axle unit integral with in-wheel motor |
CN101638052A (en) * | 2009-08-21 | 2010-02-03 | 山东大学 | Wheel assembly with integration of independent driving, steering, suspending and braking |
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2011
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Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
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EP0878332A1 (en) * | 1997-05-16 | 1998-11-18 | Conception et Développement Michelin | Unit comprising a wheel and a suspension integrated in the wheel hub |
WO2008035455A1 (en) * | 2006-09-19 | 2008-03-27 | Ntn Corporation | Sensor-equipped axle unit integral with in-wheel motor |
CN200953505Y (en) * | 2006-10-09 | 2007-09-26 | 上海燃料电池汽车动力系统有限公司 | Composite axle planetary frame outputting external rotor hub electric machine structure |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102582417A (en) * | 2012-02-24 | 2012-07-18 | 无锡永凯达齿轮有限公司 | Speed-reducing type wheel electric drive system of electric vehicle |
CN103707749A (en) * | 2013-12-11 | 2014-04-09 | 同济大学 | Integrated single-trailing-arm gear-reducing type electric wheel drive system |
CN103707749B (en) * | 2013-12-11 | 2016-11-16 | 同济大学 | A kind of integration single longitudenal arm gear speed-reducing type wheel power drive system |
CN103832271A (en) * | 2014-02-27 | 2014-06-04 | 浙江工业大学之江学院工业研究院 | Independent drive independent steering mechanism of electric vehicle |
CN108313889A (en) * | 2018-01-03 | 2018-07-24 | 徐亚杰 | A kind of Super High creeping formwork auxiliary hoisting device |
CN108313889B (en) * | 2018-01-03 | 2020-04-28 | 山东淄建集团有限公司 | Hoisting device is assisted to super high-rise creeping formwork |
CN110001381A (en) * | 2019-04-16 | 2019-07-12 | 智导灵(苏州)智能科技有限公司 | A kind of new-energy automobile wheel side separated type drive assembly |
CN111186269A (en) * | 2020-01-21 | 2020-05-22 | 同济大学 | Integrated symmetric support single-swing-arm suspension wheel side electric driving system |
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