DE102008049105A1 - Flywheel for drive train of motor vehicle, has two flywheel elements and spring- and damping-system arranged in between flywheel elements, where spring- and damping-system has two stages - Google Patents

Abstract

The flywheel (100) has two flywheel elements (102,104) and a spring- and damping-system (106) arranged in between the flywheel elements. The spring- and damping-system has two stages (108,112), where the former stage is formed as a damped stage. The latter stage is formed as damping free stage and the two stages are connected in series. The latter stage has multiple compression spring pairs which are connected in series.

Description

The The invention relates to a flywheel for a drive train a motor vehicle.

Out In practice, it is known that in a drive train of a motor vehicle Spring and damping systems are integrated. Become though such spring and damping systems used is their Observe vibration behavior. It should also be noted that the Spring and damping systems transmit the rated torque and that at low speeds high rotational nonuniformities occur in a prime mover and transmitted to the drive train can be. To the transmission of the nominal torque over to be able to ensure a suspension are proportionate rigid springs required, for example at a rated torque of 600 Nm springs with a spring rate of 50 Nm / degree twist. Such However, springs cause only slight rotational irregularities can be compensated.

From the DE 35 45 857 C1 are two-mass flywheel with spring and damping systems are known in which in the effective direction a suspension with one or more dampers, which are designed as slip clutches for connecting a first flywheel element and a second flywheel element is connected in series such that the resonance frequency as possible is slightly below the idle speed of a prime mover, so that the resonance frequency can be stimulated practically only when starting the engine. The suspension in the direction of action is constructed by a plurality of parallel spring elements, namely by helical compression springs.

From the DE 36 09 149 C2 is another two-mass flywheel with spring and damping system is known, in the direction of action two suspensions with multiple dampers are connected in parallel and in series. A first suspension may be referred to as a first damped stage together with a first damper, and a second suspension together with a second damper may be referred to as a second damped stage. This is to use the damping without torque jump.

It has been shown to improve the operating performance of known flywheels provided drive trains is unsatisfactory.

Of the Invention is based on the object, a flywheel available to provide, with which the operating behavior of a particular improved at a load change between pulling and pushing operation can be.

The Solution of this problem is inventively with the features of claim 1.

According to the The invention is in a flywheel with a first flywheel element, a second flywheel element and a spring element arranged therebetween. and damping system comprising a first and a second Stage, wherein the first stage as a damped stage is formed, provided that the second stage low-attenuation, is designed in particular damping-free, the first and the second stage are connected in series. In the first stage So it is deliberately parallel to spring elements in operation especially at high speeds to a self-locking with the Series of free paths tend to provide cushioning At each twist causes a damping and not only in a starting phase like a flat spring acts but also during load changes at high speed their effect unfolds and thus improves the operating behavior. On the other hand, the low-loss, In particular, damping-free stage achieves that in general Driving occurring different speeds due to load changes remain virtually undamped and thus a drive train Energy is not deprived by damping elements, which also causes The efficiency of a powertrain with good vibration behavior can be improved. The required for resonant frequencies Damping is characterized by the as a damped stage trained first stage provided.

According to one further preferred embodiment of the invention is provided that the second stage at least a first, preferably a plurality Compression spring pair has. Such an embodiment, in which preferably cylindrical compression springs are used, is particularly low friction, in particular frictionless and thus low in attenuation or damping executable and preferably connected in series. in the However, it is also possible within the scope of the invention instead of compression spring pairs to use bending torsion springs.

According to one further preferred embodiment of the invention is provided that the first and the second stage with respect to a common axis of rotation are arranged on different radii of action, the second Stage preferably on a larger effective radius and in particular radially outward of the first stage is arranged. In such an embodiment can be the flywheel according to the invention with a small space realize.

According to a further preferred embodiment of the invention, it is provided that the first stage has at least one first spring element, which as a frictional spring, in particular Bow spring is formed. Such a spring element-allows to build a flywheel according to the invention of a few elements.

According to one further preferred embodiment of the invention is provided that the first stage parallel to the first spring element as a damping element has at least one friction element. This can be high To implement damping, but this is not too Loss of efficiency of a drive train of a motor vehicle leads, since the second stage in driving a low-loss, in particular damping-free connection between the input side and the output side of the flywheel is provided, too can be referred to as decoupling.

According to one further preferred embodiment of the invention is provided that the first stage at least a first and a second damping region preferably, the effect of the damping areas depending on a twist angle, wherein preferably the second damping region active elements has, which only after passing through a backlash effect unfold. By such, as progressive to be called damping, in particular, the damping increases gradually will be, energy decoupling from the powertrain on the necessary minimum reduced.

According to one further preferred embodiment of the invention is provided the first stage has at least one damping element whose Damping increases with increasing centrifugal force. This is it possible, one of the starting or driving situations adapted To provide cushioning, eliminating excessive Energy outcouplings from the drive train are targeted counteracted can. An attenuation depending on the centrifugal force is particularly advantageous for load changes at high speed.

According to one further preferred embodiment of the invention is provided that the first and the second stage with respect to a common axis of rotation are arranged on different radii of action, the second Stage preferably on a larger effective radius and in particular radially outward of the first stage is arranged. Thus stands for second stage springs a relatively large amount of space available so that correspondingly large angles of rotation constructively provided can be. In such a configuration leaves nevertheless the flywheel according to the invention Overall realize with a small space.

Further yield advantageous embodiments and refinements of the invention from the subclaims as well as from the description in connection with the drawings.

there demonstrate:

1 An equivalent circuit diagram of a particularly preferred first embodiment of a flywheel according to the invention,

2 an equivalent circuit diagram of a particularly preferred second embodiment of a flywheel according to the invention,

3 an equivalent circuit diagram of a particularly preferred third embodiment of a flywheel according to the invention,

4 an equivalent circuit diagram of a particularly preferred fourth embodiment of a flywheel according to the invention, and

5 a diagram illustrating the operation of a flywheel according to the invention.

In the equivalent circuit diagram of a particularly preferred first embodiment of a flywheel according to the invention 100 according to 1 are a first flywheel element 102 and a second flywheel element 104 shown via an interposed spring and damping system 106 connected to each other. The spring and damping system 106 indicates a first step 108 as a starting stage 110 is formed, and a second stage 112 on that as decoupling 114 is trained.

In the spring and damping system 106 formed in a common housing (not shown) are the first and second stages 108 . 112 connected in series, the connection via a rotary element 116 is made.

Inside the case sits the second stage 112 , the input side with the first formed as a rotational mass body flywheel element 102 is connected, radially outside the first stage 108 , in turn, the output side with the second flywheel element 104 is connected, which in turn is designed as a rotational mass element.

The second stage 112 is made up of several friction-free compression spring pairs 118 constructed, wherein the compression spring pairs 118 in cages (not shown) are arranged, on the one hand by an input disc 120 and on the other hand by one with the rotary member 116 connected output disk 122 are formed. Inside the cages, a first compression spring is supported 124 and a second Druckfe of the 126 the compression spring pairs 118 at a zero position element 128 from. The decoupling 114 is designed for the rated torque of about 500 Nm, the spring rates of the springs 124 . 126 total 30-40 Nm / degree twist, for which purpose preferably two or more compression spring pairs are connected in series.

The first stage 108 has as a first spring element 130 at least one bow spring 132 on, to which a first damping element 134 and a second damping element 136 are connected in parallel. The first damping element 134 is a friction element which is composed of friction plates (not shown), which at each rotation of an output side 138 relative to an input page 140 create a friction and thus a damping. Through the first damping element 134 Thus, a first damping range is created, which dampens with each rotation. The spring rate of the bow spring 132 Total is in the range of 4-20 Nm / degree twist, and this bow spring engages directly or after passing through a free path while being damped. The bow spring should be designed so that only about 40-60% of the rated torque can be transmitted through this, until the bow spring stops.

Also the second damping element 136 has friction plates (not shown), which, however, unfold their friction and thus damping effect only after passing through a torsional backlash. The first and / or the second damping element 134 . 136 is carried out with a centrifugal force reinforcement, which can be provided in a structurally simple manner by a kind of pendulum, which acts on one or more displaceable in the axial direction friction plates.

The operation of the flywheel according to the invention, to explain the diagram in 5 serves as follows.

An internal combustion engine of a motor vehicle should be started at the operating point "0", the rotational speed and the torque M output by the internal combustion engine are initially 0. In the interval between the operating points "0" and "1", a starter turns the internal combustion engine into one Range of about 150 to 250 U / min, in particular 180 U / min, such that starting from this time ignitions of a combustion mixture can take place. In the interval between the operating points "1" and "2", the internal combustion engine reaches its idling speed of about 750 rpm, with rotational nonuniformities occurring in the starting stage at the intervals "0" - "1" and "1" - "2" 110 be steamed.

If the internal combustion engine has reached its idling speed, an action of the driving operation can be carried out in an interval "2" - "3", wherein the internal combustion engine outputs a positive torque and, for example, is accelerated to a rotational speed of 1500 rpm. In the interval "2" - "3" occurring rotational nonuniformities are through the second stage 112 that as driving decoupling 114 is formed, decoupled from the drive train, wherein the driving decoupling 114 without damping and the starting stage 110 is in a stop position, so that no damping occurs.

Now results in an operating situation, such as driving behind another vehicle in which a vehicle from a train operation, that is, from a power output of the internal combustion engine (torque "plus") must switch to a coasting operation (torque "minus") - as in the Interval "3" - "4" shown, acts in addition to the driving decoupling 114 also the starting level 110 in which in a starting stage 110 a damping takes place. Such an effect does not show flywheels according to the prior art, because these are the existing damping springs, which are formed as bow springs, in a state of self-locking and fall through a free path, which due to the necessarily hard springs of driving decoupling to a humming and leads to shocks, which are also associated with wear. On the other hand, the starting stage works 110 according to the invention with its targeted use of a frictional backlash dampening, and it thus improves the performance of the drive train. The starting stage 110 acts in the same way at a renewed power request in the interval "4" - "5", so that the starting stage 110 is more than a simple starting stage according to the prior art.

By the invention it is possible and in the preferred embodiment also desired that a Verdrehweg in driving decoupling 114 from 30 ° to 50 °, preferably 40 °. The twisting path in the starting stage 110 is preferably up to 80 °, in particular at 50 ° rotation. The large permissible Verdrehwege go with a lowered total spring rate of the flywheel 100 associated.

The particularly preferred first embodiment of a flywheel according to the invention 100 may in the context of the invention as a flywheel with a starting stage 110 as an internal damper and a low-friction outer damper low spring rate are performed.

An inventive flywheel 200 according to a in 2 shown with an equivalent circuit shown particularly preferred second off Guidance differs from the flywheel 100 according to the first embodiment, only in a detail change of the first stage 208 in that, for elements of the second embodiment corresponding to elements of the first embodiment, reference numerals have been used which are different from the first embodiment 100 are increased. The corresponding description is hereby expressly referred to and incorporated by reference.

The function of the flywheel 200 is according to the function of the first flywheel 100 , again with the starting stage 210 not only in an initial phase effect.

Like the first embodiment, the second embodiment has a first flywheel element 202 , a second flywheel element 204 and an interposed spring and damping system 206 on which next to the first stage 208 an external second stage 212 having. The first stage 208 is again a starting level 210 , and the second stage 212 a decoupling 214 , With her compression spring pairs 218 , an input disk 220 , an output disk 222 , first and second springs 224 . 226 and a zero position element 228 equals the second stage 212 the second embodiment of the first embodiment of a flywheel according to the invention 100 , As in the first embodiment are in the spring and damping system 206 the first and the second stage 208 . 212 via a rotary element 216 connected in series.

Also the first stage 208 The second embodiment has a first spring element 230 and a first and a second damping element 234 . 236 on, wherein the first spring element 230 however, between an output side 238 and an input page 240 is arranged such that the spring action begins after passing through a game. This lowers the spring rate of the as a starting stage 210 trained first stage 208 and thereby improves the resonance behavior. This in connection with the first spring element 230 as bow spring 232 is formed, used device is with 250 designated. Preferably, at least one of the damping elements 234 . 236 designed so centrifugally operated that with increasing centrifugal force, the friction and thus the damping is increased.

An in 3 on the basis of an equivalent circuit shown flywheel 300 According to a particularly preferred third embodiment of the invention may be formed as a development of the first or second embodiment, in which case a first stage 308 with or without a control disc 350 is trained. Since the third embodiment is a development of the first or second embodiment, for elements corresponding to the first and second embodiment, reference numerals are used to 200 respectively. 100 are increased. The corresponding description is expressly referred to and incorporated by reference.

Of the first and second embodiments, the third embodiment differs in the configuration of the second stage 312 , which is a second rotation element 360 which is connected between series-connected compression springs or - as in 3 shown - low-friction bending torsion springs 362 . 364 is arranged.

In the third embodiment, the first spring element 330 , which with the entire starting stage 310 within the second stage 312 is arranged, a very soft spring to effect a good decoupling. By the first and the second friction element 334 . 336 However, a flat spring rate is effected, which is positive for the resonance behavior in a start-up phase. The friction elements 334 . 336 cause a stepped play friction as in the first and the second embodiment.

A flywheel 400 according to the in 4 shown equivalent circuit diagram corresponds in essential elements to the flywheels described above 100 . 200 . 300 , so as to designate elements of the flywheel 400 , which correspond to elements of the first, second and third embodiment, reference numerals have been used to 300 . 200 respectively. 100 have been increased. The corresponding description is hereby incorporated by reference and referenced.

The flywheel 400 points between a first flywheel element 402 and a second flywheel element 404 a spring and damping system 406 on, at which a first stage 408 and a second stage 412 are formed. The second stage 412 is like the second stage 312 of the third embodiment, so that reference is expressly made to and reference to this embodiment in this regard. Also in the function, the fourth embodiment is similar to the other embodiments, but the decoupling is better. In all preferred embodiments, it is essential that in the decoupling stages a coupling via a damping does not exist.

In contrast, the first stage 408 of the third embodiment to the first stages of the earlier embodiments differently shaped by a friction stage 470 and a decoupling stage 472 are connected in series.

In the friction stage 470 are a first damping element 435 and a second damping element 437 connected in parallel, the Dämp fung elements 435 and 437 essentially the damping elements 134 and 136 correspond, but not connected in parallel to a spring element. The friction elements 435 . 437 cause a stepped play friction for damping a Zwischenflanschresonanz and lowering the overall resonant frequency of the flywheel 400 , At any angle of rotation between the first flywheel element 402 and the second flywheel element 404 To prevent the friction level has a stop 474 on, which is similar to a control disk is formed.

The decoupling stage 472 the first stage 408 has a first spring element 431 on, which is formed without friction and damping and in particular designed as a bending torsion spring or helical spring.

For completeness, it should be noted that in the second stage 412 first springs 424 and second springs 426 , which are friction-free compression spring, over an element 460 are connected to each other, the first stage 412 in total via a rotary element 416 connected to the second stage.

at All particularly preferred embodiments will be existing conflict of interest between the highest possible Friction (damping) at a resonance speed on the one hand and the lowest possible friction during driving in solved a particularly favorable ratio.

The Flywheel according to the invention and in particular its particularly preferred embodiments are preferred for powertrains of a passenger car provided with 4-cylinder or 6-cylinder drive and manual transmission, But they can also be beneficial in terms of converters and / or hybrid drives are used.

100

flywheel

102

first flywheel element

104

second flywheel element

106

Feather- and damping system

108

first step

110

starting stage

112

second step

114

decoupling

116

rotating member

118

Spring pairs

120

input disc

122

output disc

124

first feather

126

second feather

128

Zero position element

130

first spring element

132

frictional bow spring

134

first damping element

136

second damping element

138

output side

140

input side

200

flywheel

202

first flywheel element

204

second flywheel element

206

Feather- and damping system

208

first step

210

starting stage

212

second step

214

decoupling

216

rotating member

218

Spring pairs

222

output disc

224

first feather

226

second feather

228

Zero position element

230

first spring element

232

frictional bow spring

234

first damping element

236

second damping element

238

output side

240

input side

250

control disc

300

flywheel

308

first step

310

starting stage

312

second step

330

first spring element

334

first damping element

336

second damping element

350

control disc

360

rotating member

362

friction bending spring

364

friction bending spring

400

flywheel

402

first flywheel element

404

second flywheel element

406

Feather- and damping system

408

first step

412

second step

416

rotating member

424

first feather

426

second feather

431

first spring element

435

damping element

437

damping element

460

element

470

friction stage

472

decoupling stage

474

attack

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 3545857 C1 [0003]
• - DE 3609149 C2 [0004]

Claims (9)

Flywheel, with a first flywheel element ( 102 ; 202 ; 302 ; 402 ), a second flywheel element ( 104 ; 204 ; 304 ; 404 ) and an interposed spring and damping system ( 106 ; 206 ; 306 ; 406 ), which comprises a first and a second stage ( 108 . 112 ; 208 . 212 ; 308 . 312 ; 408 . 412 ), the first stage being a damped stage ( 108 ; 208 ; 308 ; 408 ), characterized in that the second stage ( 112 ; 212 ; 312 ; 412 ) low attenuation, in particular attenuation-free is formed, wherein the first stage ( 108 ; 208 ; 308 ; 408 ) and second stage ( 112 ; 212 ; 312 ; 412 ) are connected in series. Flywheel according to claim 1, characterized in that the second stage ( 112 ; 212 ; 312 ; 412 ) at least a first, preferably a plurality of compression spring pairs ( 118 ; 218 ), which are preferably connected in series. Flywheel according to claim 1 or 2, characterized in that the first and the second stage ( 112 ; 212 ; 312 ; 412 ) are arranged on different effective radii with respect to a common axis of rotation, wherein the second stage ( 112 ; 212 ; 312 ; 412 ) preferably over a larger effective radius, in particular in relation to the first stage ( 108 ; 208 ; 308 ; 408 ) is arranged radially on the outside. Flywheel according to one of claims 1 to 3, characterized in that the first stage ( 108 ; 208 ; 308 ) at least one first spring element ( 130 ; 230 ; 330 ), which is designed as a frictional spring, in particular bow spring. Flywheel according to one of claims 1 to 4, characterized in that the first spring element ( 130 ; 230 ; 330 ) only after passing through a free path (torsional backlash), especially after a backlash of 10 ° -20 °, preferably 15 ° acts, Flywheel according to claim 4 or 5, characterized in that the first stage ( 108 ; 208 ; 308 ) parallel to the first spring element ( 130 ; 230 ; 330 ) has at least one friction element as a damping element. Flywheel according to one of claims 1 to 6, characterized in that the first stage ( 108 ; 208 ; 308 ) has at least a first and a second damping region, wherein preferably the effect of the damping regions in dependence on a twisting angle, wherein preferably the second damping region has active elements, which unfolded their effect only after passing through a torsional backlash. Flywheel according to one of claims 1 to 7, characterized in that the first stage ( 108 ; 208 ; 308 ) has at least one damping element whose damping increases with increasing centrifugal force. Flywheel according to one of claims 1 to 8, characterized in that the first and the second stage ( 108 . 112 ; 212 ; 308 . 312 ; 408 . 412 ) are arranged on different effective radii with respect to a common axis of rotation, wherein the second stage ( 112 ; 212 ; 312 ; 412 ) preferably over a larger effective radius, in particular in relation to the first stage ( 108 ; 208 ; 308 ; 408 ) is arranged radially on the outside.