Method of operating a drive train and drive train

专利摘要:
In a method for operating a drive train with a drive shaft (2), one connected to a power grid (12) electric drive machine (4) and with a differential gear (3) with three input or output drives, wherein an output to the drive shaft (2 ), a drive with the drive machine (4) and a second drive with a differential drive (5) is connected, the differential drive (5) is operated only by motor, while the drive machine (4) is operated by a motor or generator, wherein the differential drive (5 ) is connected via a rectifier (19) to the power grid (12).
公开号:AT514281A2
申请号:T419/2013
申请日:2013-05-17
公开日:2014-11-15
发明作者:Gerald Dipl Ing Hehenberger
申请人:Gerald Dipl Ing Hehenberger；
IPC主号:

专利说明:

17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA P. 03/41
• • • • • • • • • • • • • • • • • • • • • • • • • • • • • 0 «• · · · · · · 0
The invention relates to a method for operating a drive train with a drive shaft, connected to a mains electrical drive machine and with a differential gear with three drives or drives, wherein an output connected to the drive shaft drive to the prime mover and a second drive to a differential drive is.
The invention further relates to a drive train with a drive shaft, connected to a mains electrical drive machine and with a differential gear with three inputs and outputs, wherein an output to the drive shaft, a drive to the prime mover and a second drive with an electric differential drive connected is.
A common problem of working machines, such as conveyors, e.g. Pumps, compressors and fans, or like mills, crushers, vehicles, etc., 13t an efficient variable speed operation. In the following, electric machines are used as examples of drive machines, but the principle applies to all possible types of drive machines such as e.g. for internal combustion engines. The most commonly used electric drives today are three-phase machines such as e.g. Asynchronous motors and synchronous motors.
The invention is based on the object to provide a method and an apparatus of the type mentioned, in which a simple construction, a change in the delivery rate of the conveyor is possible.
This .Aufgabe is solved in a method of the type mentioned fact that the differential drive is operated only by motor, while the prime mover is operated by a motor.
This task is further solved with a. Drivetrain of the type mentioned in that the differential drive is connected via a rectifier to the power grid. P.003 / 041 17/05/2013 19:59 2/39 Ri68 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA P. 04/41
The core of a differential system is a differential gear, which in a simple embodiment is a simple planetary gear stage with three Anl drives, with one output connected to the drive shaft of a work machine, a first drive to the prime mover and a second drive to a differential drive. Thus, the machine can be operated variable speed at constant speed of the prime mover by the differential drive compensates for the speed difference.
With the differential drive, the amount delivered by the work machine can be increased by increasing the constant power of the prime mover by the variable power of the differential drive.
If the inverter usually used for an electric differential drive is replaced by a rectifier 19, this is advantageous because it usually has a higher efficiency than an inverter and is also much more robust and cost-effective.
If the differential drive is operated only by a motor, while the drive machine is operated by a motor or generator, the method according to the invention and the drive train according to the invention can be used very well for pump turbines which are used, for example, in storage power plants.
Preferred embodiments of the invention are the subject of the dependent claims.
Hereinafter, preferred embodiments of the invention will be explained with reference to the accompanying drawings. E3 shows:
1 shows the principle of a differential system for driving a pump,
Fig. 2 shows another embodiment of a differential system BEER & PARTNER PATENTA S. 05/41 19/59/2013 19:59 3 / 39R168 P.004 / 041 17/05/2013 19:58 +4315264245
Fig. • ································································································ Fig. 4 shows the speed · 'and performance parameters of a differential system of a pump, Fig. 5 shows another embodiment of a differential system with a simplified differential drive, Fig. 6 the 7 shows a further embodiment of a differential system with a gearshift stage, FIG. 8 shows the speed and power parameters resulting from FIG. 7, FIG. 9 shows a further embodiment of a differential speed system with reduced speed range FIG. 10 shows the speed and power parameters resulting from FIG. 9, FIG. 11 shows the possible speed and power parameters resulting from FIG. 9 for a so-called pump turbine, FIG. 12 shows a further embodiment FIG. 13 shows a control system for damping driveline vibrations. FIG.
Despite high electrical power consumption, three-phase machines at standstill are not able to deliver this power completely mechanically, which is reflected in high losses and a low starting torque. At the same time, the current consumption of a three-phase machine at the start of speed zero typically corresponds to 17/05/2013 19:59 4/39 R168 P.005 / 041 17/05/2013 19:58 +4315264245
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Therefore, a three-phase machine must be designed to be large enough so that it can deliver from standstill to a torque corresponding to the rated torque, and is therefore often oversized. Electrical machines are therefore, also for this reason, instead of being connected directly to a network, often performed in combination with a frequency converter as a variable speed drive. This can indeed be a start with high torque of zero speed without burdening the network, but the solution is expensive and associated with significant efficiency losses. A comparatively more cost-effective and also better in terms of efficiency alternative is the use of differential systems, for example, according to AT 507 394. Basic limitation here is that depending on the gear ratio of the differential stage only a relatively small speed range or in so-called differential mode practically no low speeds the drive shaft of a working machine can be achieved. CJm d.ie3 to realize there are different ways. According to German Utility Model No. 20 2012 101 708.3, for example, you can set the transmission ratio of the differential gear to 1. On this basis, one can drive the complete driveline with the differential drive, or bring the prime mover on Synchrondrehdrehlahl uhd synchronize them subsequently with the network.
Disadvantage of this solution is that the differential drive or its, Frequen, converter is dimensioned much smaller than the prime mover and therefore only one. can deliver correspondingly small torque.
To synchronize a prime mover with either the mains under load {e.g. electric machines coupled directly to the network) or in a range of rotational speeds with high available torque (such as in internal combustion engines) and in addition the working machine with maximum or maximum speed 07/41 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA p. ···················································································· ···
To be able to start design torque of the drive train from zero speed and preferably to bring to synchronous speed, the start-up can be e.g. take place in 3 phases as follows:
Phase 1: The prime mover is preferably connected to the grid with so-called star / delta connection or alternatively (in a particularly network-saving method) first brought to (at least approximately) synchronous speed with an additional device and then synchronized with the network. In the case of an internal combustion engine, this is simply started and then started up. In this case, the drive machine remains during startup, apart from the mass moment of inertia caused by reaction forces from the second drive of the differential gear, largely free of external mechanical loads. In retrospect, this means that until the prime mover has reached its rated speed, a correspondingly small driving torque acts on the drive shaft of the driven machine.
Phase 2: Since now the full torque of the prime mover is available, in the second phase the actual acceleration and starting of the driven machine under load begins by delaying the second drive of the differential gear stage by means of a synchronization brake.
Phase 3: As soon as the drive shaft of the second drive of the differential system is in the control speed range of the differential drive, this assumes the speed control of the drivetrain and the synchronization brake is released.
Fig. 1 shows the principle of a differential system for a drive train using the example of a pump. In this case, the working machine 1 is the rotor of a pump, which is driven by a drive machine 4 via a drive shaft 2 and a differential gear 3. The prime mover 4 is preferably a medium-voltage three-phase machine, which is connected to a network 12, which in the example shown is a medium-voltage network due to a medium-voltage three-phase machine. The chosen 17/05/2013 20:00 6/39 R168 P.007 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 08/41 • f ••••• 9 • ··· • ·
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Voltage level, however, depends on the application and v.ä. the performance level of the 'prime mover 4 and can have any desired voltage level without affecting the basic function of the system according to the invention. According to the number of pole pairs of the prime mover 4 results in a design-specific operating speed range. The operating speed range is that speed range in which the drive machine 4 can deliver a defined or desired or required torque or, in the case of an electric drive machine, can be synchronized with the network 12. A planet carrier 7 is connected to the drive shaft 2, a drive machine 4 with a ring gear 8 and a sun gear 9 of the differential gear 3 with the differential drive 5. The core of the differential system in this embodiment is thus a simple Planetengetriebe3tufe with three inputs or outputs, an output with the drive shaft 2 of the working machine 1, a first drive with the drive machine 4 and a second drive with the differential drive 5 is connected.
In order to optimally adjust the speed range of the differential drive 5, an adjustment gear 10 between the sun gear 9 and the differential drive 5 is implemented. As an alternative to the spur gear stage shown, the adjustment gear 10 can also be multi-stage, for example, or designed as a toothed belt or chain drive. With the adjustment gear 10 can also be a misalignment for the. Implement differential drive 5, which allows a simple design of the differential drive 5 due to the coaxial arrangement of the working machine 1 and the drive machine 4. With the differential drive 5, a motor brake 13 is connected, which brakes the differential drive 5 when needed. Electrically, the differential drive 5 is connected to the network 12 by means of a preferably low-voltage frequency converter, comprising a motor-side inverter 6a and a grid-side inverter 6b, and a transformer 11. The transformer compensates for any existing voltage differences between the Net2 12 and the grid-side inverter 6b and can be dispensed with voltage equality between the engine 4, the grid-side inverter 6b and the network 12. The inverters 6a and 6b are connected by a DC intermediate circuit and can be locally locally if necessary
BEER & PARTNER PATENTA p. 09/41 • et · · · I · · · · · · · · · · ···· »» «
··· 0 ... be separated, wherein preferably the motor-side inverter 6a is positioned as close as possible to the differential drive 5. An essential advantage of this concept is that the drive machine 4 can be connected directly to a network 12, that is to say without elaborate power electronics. The compensation between the variable rotor speed and the fixed speed of the network-connected drive machine 4 is realized by the variable-speed differential drive 5.
The torque equation for the differential system is:
Torque ^, FF ^ snziaiantrieb = DrehmomentAncneteweiie * y / X / wherein the size factor y / x is a measure of the gear ratios in the differential gear 3 and the adjustment gear 10. The power of the differential drive 5 is substantially proportional to the product of percent deviation of the pump speed from its base speed x drive shaft power. Accordingly, a large speed range basically requires a correspondingly large dimensioning of the differential drive 5. This is also the reason to see why differential systems for small speed ranges are particularly well suited, but in principle any speed range can be realized.
A differential drive 5 for a pump as a work machine 1, for example, has an output of about 15% of the total system power. This in turn means that with the differential system no low speeds can be realized on the working machine 1. If the work machine 1 must be brought from zero speed with high torque in its working speed range (this is the speed range in which the work machine 1 essentially works), this can only be realized by the differential drive 5 braked (either electrically or by means of motor brake 13th ) and the prime mover 4 is switched to the mains. The working machine 4, in turn, can hardly apply the rated torque from a standing position, or draws a rated current of up to 7 times in order to accelerate approximately to synchronous speed.
By using a so-called star / delta circuit, you can indeed 17/05/2013 20:01 8/39 R168 P.009 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 10/41 • e • ·
Reducing the starting flow reduces the realizable starting torque.
An improvement can be achieved z. B., by the differential drive 5 is brought at the beginning of the startup to its maximum possible operating speed. Due to external loads while the work machine 1 remains in a range of low speed. As a result, the prime mover 4 is brought to a speed which depends on the rotational speed of the working machine 1 on the one hand and, gear ratio of the differential gear 3 and a possibly existing adjustment gear 10 on the other hand inevitably sets. Subsequently, the differential drive 5 is controlled so that its speed remains within its control speed range, while the prime mover 4 is connected to the network 12 with or without so-called star / delta connection. The speed control or braking of the differential drive 5 is preferably carried out electrically by the inverter 6a, 6b, or by means of motor brake thirteenth
The engine brake 13 can also be used to protect the differential drive 5 from overspeeding when z. B. the prime mover 4 fails and the work machine stops or 1 rotates in the opposite direction.
Fig. 2 shows another embodiment of a differential system. The drive train shown here also has, as in FIG. 1, a working machine 1, a drive shaft 2, a differential gear 3, a drive machine 4 and a differential drive 5, which by means of a frequency converter 6 (consisting of motor-side and network-side inverter - here shown simplified as a unit ) and a transformer 11 connected to the network 12 i3t. Again, the differential drive 5 is connected by means of a matching gear 10 to the differential gear 3. In addition, however, a clutch 15 is implemented between the adjustment gear 10 and the differential gear 3.
A synchronization brake 14 acts on the sun gear 9 and thus on the entire drive train. When starting up in a first step 17/05/2013 20:01 9/39 R168 P.010 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA S. 11/41
the differential drive 5 and, the adjustment gear 10 decoupled by the clutch 15 from the rest of the drive train. If the prime mover 4 is then started up and connected to the grid, the sun gear 9 rotates freely and no appreciable torque can build up in the entire drive train. Thus, even in this case, the working machine 1 remains in one, low-speed range and the drive machine 4 can be synchronized with the network 12 without significant external counter-torque.
To the. To avoid the above-described effect of the high starting current when synchronizing the prime mover 4, either a star-delta circuit can be implemented or the prime mover 4 can be replaced by an auxiliary device - e.g. a small variable speed drive - brought to (approximately) synchronous speed and then synchronized with the network 12. Alternatively, with the clutch 15 closed, as already described with reference to FIG. 1, the drive machine 4 can be brought to the speed with the differential drive 5. Although the prime mover 4 can not be accelerated up to its synchronous rotational speed, at least the starting current that arises is smaller. The clutch 15 is then opened again.
Once the prime mover 4 has been accelerated over a certain speed and the work machine 1 rotates only slowly, turns on the sun gear 9 a corresponding to the transmission ratio of the differential gear 3 high speed, which (taking into account the adjustment gear 10) over the allowed control speed range for the Differential drive 5 is located.
The control speed range is the speed range in which the differential drive 5 operates to realize the working speed range of the working machine 1 can. The control speed range is thereby v.a. determined by the voltage, current and speed limits specified by the manufacturer. In this phase, the differential drive 5 can not be connected to the network 12. In a further step, therefore, with the synchronization brake 14, the second drive of the differential gear 3 connected to the sun gear 9 is decelerated to a rotational speed which is within the control rotational speed range of the differential drive 5. Subsequently, the P.011 / 041 17/05/2013 20:02 10 / 39R168 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 12/41 β • · • · Ο 9 • · ft ·
• · • · · · · β e • · • 9 9 · Ο · «· · · β ·
Differential drive-side part of the clutch 15 (preferably by means of differential drive 5) preferably synchronized with the speed of the second drive of the differential gear 3 and then the clutch 15 is closed. The clutch 15 is preferably a positive-locking dog clutch or a frictionally engaged multi-plate clutch. An advantage of the non-positive multi-plate clutch is that, if designed for it, no synchronization of the two coupling halves is necessary.
By actuating the synchronization brake 14, the drive shaft 2 is inevitably accelerated, the torque available for this purpose being determined by the minimum of the braking force acting on the drive shaft 2 of the synchronization brake 14 on the one hand and the overturning moment of the drive machine 4 on the other hand. That In contrast to the starting options according to the prior art can da3 multiple rated torque as starting torque of zero speed away can be realized here because the typical tilting torque of a three-phase machine is about 2 to 3 times their rated torque. Basically, this start-up method can also be applied to z.JB. Internal combustion engines are used, which is sometimes necessary because they can only generate a torque in the partial speed range, which is much lower than their rated torque.
As a synchronization brake 14, for example, a disc brake (= mechanical brake) is used, so this can serve as a service and safety brake for the differential drive 5. Thus, the synchronization brake 14 can basically fulfill the function of the motor brake 13 shown in FIG.
Alternatively, however, any type of brake can be used. In particular, here offer so-called retarder. First of all, the group of hydrodynamic retarders (= hydraulic brake) should be mentioned here. Hydrodynamic retarders usually work with oil or water, which is directed into a converter housing if necessary. The converter housing consists of two rotationally symmetric and opposed paddle wheels, and previously a rotor, which is connected to the driveline of the system, and a fixed stator. The rotor accelerates the supplied 17/05/2013 20:02 H / 39R168 P.012 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA P. 13/41
• · • · e ·
oil and the centrifugal force pushes it outwards. The form of the rotor blades guides the oil into the stator, which in turn induces a braking torque in the rotor and then slows down the entire drive train in a further Folg®. In an electrodynamic · retarder (= electric brake), e.g. an eddy current brake, are e.g. two steel discs (rotors), which are not magnetized, connected to the drive train. In between lies the stator with electric coils. When current is activated by activation of the retarder, magnetic fields are generated which are closed by the rotors. The opposing magnetic fields then generate the braking effect. The resulting heat is e.g. discharged through internally ventilated rotor discs again.
An essential advantage of a retarder as service brake is its freedom from wear and good controllability.
The system may also be used to operate the prime mover 4 in phase shifting mode, i. That is, the prime mover 4 can supply reactive power to and from the network 12 without operating the work machine 1. This applies in particular to energy production plants.
FIG. 3 shows a further embodiment of a differential system with a transmission precursor S. Through this Getriebevorstufel6 the speed range for the drive shaft 2 and for the work machine 1 according to the transmission ratio of the gear precursor 16 can be adjusted. The use of a gear precursor 16 is then necessary or advantageous if, due to the technical parameters of e.g. cost engine 4 and an efficient differential system resulting speed level does not meet the required working speed range of a working machine 1. A resulting advantage is that, provided that the gear precursor 16 as shown a® spur gear, the differential drive 5 can be positioned without a matching gear 10 of FIG. 1 and 2 coaxial with the engine 4 on the side facing away from the drive machine of the differential gear 3. In order to achieve thereby possibly, required higher transmission ratio in the differential gear 3, offers 17/05/2013 20:03 12 / 39R168 P.013 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 14/41 ·· ·· 9 ·· 9 9 »999 • 9 9 9 9 * Often ·· θ 9 9 Οβ · O ···· 9 99 90999« · o • 9 9 9 9 9 9 <J3 9 99 90 O OOOOOO 0 9 9 instead of using simple planets, so-called stepped planets. These stepped planets each consist of two rotatably connected gears with different diameters and preferably different toothing geometry. The ring gear 8 is then engaged with the smaller diameter gear of the stepped planet, and the sun gear 9 with the second gear of the stepped planet. The connecting shaft 26 between the differential gear 3 and the differential drive 5 is preferably an electrically non-conductive fiber composite shaft. If the connecting shaft 26 is an electrically conductive shaft, then preferably an insulating element between the
Install differential gear 3 (or if the adjustment gear 10 available) and the differential drive 5 to keep unwanted electrical currents from the differential gear 3.
Thus, the differential system consists of a smallest possible number of components and also has an optimal overall efficiency. The motor brake 13 also fulfills the function of the synchronization brake 14 from FIG. 2 in the configuration shown. The disadvantage of this embodiment compared to that according to FIG. 2 is that the differential drive 5 must be designed for the starting operation for a higher speed, the differential drive 5 is preferably separated from the network at speeds above the control speed range. Thus, speeds outside the control speed range only have to be endured mechanically. To make matters worse, that the transmission ratio of the differential gear 3 must be higher than for the solution of FIG. 2, because here the adjustment gear 10 is missing. Basically, however, is also for the variant like. Fig. 3, the additional use of a matching gear 10 possible, whereby the transmission ratio of
Differential gear 3 can be smaller. In addition, a clutch 15 and a synchronization brake 14 between the second drive of the differential gear 3 and the sun gear 9 and the differential drive 5 can be implemented.
Basically, this embodiment can also be used for power generation plants, in particular wind turbines, as a work machine 1, in this case turns in 17/05/2013 20:03 13 / 39R168 P.014 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 15/41 • · · · · · · ·
Comparison to e.g. a pump as a working machine 1, the Leistungsflu3srichtung and the Äntriebsmaschine 4 operates as a generator. If necessary, one or more further transmission stages can be provided between the transmission precursor 16 and the working machine 1, which are then preferably designed as a planetary gear stage.
Another advantage of this embodiment with gear precursor 16 is that a coaxial hollow shaft 27 can be realized to the working machine 1 in a simple manner. By means of this hollow shaft 27, the rotating Arbeitsmaachine 1 can be supplied in a simple manner electrically or hydraulically. In this case, preferably a rotary transmission 28 is applied to the working machine averted side of the gear precursor. In principle, a mechanical linkage can also be guided in the bushing 27 and can therefore be moved by translatory or rotary movement, e.g. the blades of a pump rotor are mechanically adjusted.
If the differential system and the transmission precursor 16 are provided as a so-called "standalone" version, the drive shaft 2 and the operating machine 4 are preferably connected by means of a coupling 17, 18.
Fig. 4 shows the speed and performance parameters of a differential system, for example for a pump. The illustration shows power and speed values for a pump al3 work machine 1, a prime mover 4 and a differential drive 5 each plotted against the speed values of the drive shaft 2 ("pump speed"). The prime mover 4 is connected to the network 12 and thus its speed ("engine speed") is constant - in the example shown, about 1,500 rpm for a four-pole three-phase machine in a 50 Ηζ network. The working speed range for the drive shaft 2 is from 68% bi3 100%, with 100% being the selected nominal or maximum point. According to the gear ratio of the differential system, the speed of the differential drive 5 ("servo speed") is from -2,000 rpm to 1,500 rpm. This means that the differential drive 5 is operated as a generator (-) and as a motor (+). Since the maximum P.015 / 041 17/05/2013 20:03 14 / 39R168 17/05/2013 19:58 +4315264245
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• Required power of the differential drive 5 in the regenerative (-) range (approximately 110 kW) is less than that in the motor (+) range (approximately 160 kW), the differential drive 5 can be used in regenerative ( -) range are operated in the so-called, field weakening, which for the differential drive 5, a higher speed - but with reduced torque - can be realized. Thus, the speed range for the working machine 1 can be extended in a simple manner.
Another way to extend the speed range for the working machine 1, offers the so-called 87Hz characteristic for the operation of the frequency converter 6. The principle is the following: Motors can typically operate in star (400V) or triangle (230V). If one operates a motor as usual with 400V in star connection, then one reaches the nominal point with 50 Hz. This characteristic is set in the frequency converter. You can also run a motor with 400V in delta connection and parameterize the frequency converter so that it reaches the 50Hz at 230V. As a result, the frequency converter reaches its rated voltage (400 V) only at 87 Hz (V3 x 50 Hz). Since the motor torque is constant up to the nominal point, a higher power is achieved with the 87 Hz characteristic. It should be noted, however, that in comparison to the star connection in the case of delta connection, the current is higher by "s / 3". That The frequency converter must be larger in size. In addition, the motor generates higher losses due to the higher frequency, for which the motor must be thermally designed. Ultimately, however, with the 87 Hz characteristic, a corresponding (V3) higher speed range is achieved with - in contrast to the field weakening - not reduced torque.
The point "T &quot; in Fig. 4, the so-called "base speed &quot; the drive shaft 2, in which the speed of the differential drive 5 is equal to zero. Ideally, this point becomes "T &quot; placed in a work area in which the plant is operated over a large time shares. In this operating point, the engine brake 13 can be activated, so that the differential drive 5 does not have to be operated and subsequently related losses and wear can be avoided. In the motor {+) area of the map, the drive is driven in parallel by the prime mover 4 and BEER & PARTNER PATENTA S. ························································································································································································································ · · »AB ·······································
Differential drive 5 driven. The sum of both powers is the drive power for the drive shaft 2 ("system performance") minus accumulating system losses. In the regenerative (-) range, the prime mover 4 must compensate for the power of the differential drive 5 ("Servo Power"), whereby the total system power ("System Power") is the drive power of the prime mover 4 ("Engine Power") less the power of the Differential Drive 5. That is, in terms of efficiency, the motor (+) region is better. This fits very well with the illustrated exemplary frequency distribution ("probability") of the load distribution during continuous operation of the system, which shows a large part of the operating time in the motor (+) range. However, due to operational reasons, operation at relatively low pump speeds is also necessary, in which case the proportionate dwell time decreases sharply with decreasing pump speed.
Basically, it should be noted that the closer the pump speed ("pump speed") at the base speed "T" to the bottom speed. is, the smaller the power flow through the differential drive 5 and thus the overall system efficiency is very high. As with increasing pump speed and the required drive power increases, however, the required size of the prime mover 4 can be reduced by the size of the differential drive 5 compared to a drive according to the prior art by the parallel drive of the drive machine 4 and the differential drive 5.
As already mentioned, the transmission ratio of the differential drive can be set to 1 according to German Utility Model No. 20 2012 101 708.3 using a differential lock. This makes it possible with the differential drive 5 accelerates the entire drive train to the synchronous speed of the drive machine 4 and then to synchronize them with the network. As a result, the differential drive 5 can optionally be switched off and the drive machine 4 drives the work machine 1 with synchronous speed alone. In addition, the differential drive 5 can drive the work machine 1 parallel to the drive machine 4, whereby a higher overall drive train performance can be realized. With the differential lock and the engine brake 13 can thus realize two stationary operating points of the drive train. In a 17/05/2013 20:04 W39R168 P.017 / 041 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA p. 18/41
Particularly cost-effective design of the differential drive is performed so poor performance, so that only the drive machine 4 with the network 12, and the differential lock is synchronized. However, this can alternatively be realized by optionally driving the output or the first drive of the differential gear 3.
Fig. 5 shows another embodiment of a differential system with a simplified differential drive. In this embodiment, the network-side inverter 6 b is replaced by a simple rectifier 19. This has a usually higher efficiency than an inverter 6b and is also much more robust and cheaper. The only restriction through the use of a rectifier 19 is that the differential drive 5 can only be operated by motor (+). If, in the opposite case, the differential system is operated only as a generator {-), the motor-side inverter 6a can be replaced by a rectifier 19 while maintaining the grid-side inverter 6b.
Fig. 6 shows the resulting from Fig. 5 speed and power parameters at the same working speed range for the drive shaft 2 as in Fig. 4 (68% -100%). Due to the fact that the differential drive 5 is operated only in the motor (+) range, the maximum power flow through the differential drive, 5 is much larger than in the example shown before. At the nominal point, the required power of the differential drive 5 ("Servo power") reaches approx. 500kW, that's 50% of the total power output {"system performance"). This has the consequence that also the frequency converter 6a, 19 must be dimensioned correspondingly large. Advantage of this variant is that the transmission ratio of the differential gear 3 may be much lower than for the variant of FIG. 3, and thus when starting the system while the maximum achievable speed of the differential drive 5 is lower. P. 018/041 17/05/2013 20:05 19/41 17/05/2013 19:58 + 43152E4245 BEER & PARTNER PATENTA S.
• · ············
Fig. 7 shows another embodiment of a differential system with a gear shift stage. In the exemplary embodiment shown, the transmission precursor 16 is expanded by a further transmission precursor 20, with a transmission ratio different from that of the transmission precursor 16. By means of switching device 21 can choose between the two transmission precursors and thus receives an adjusting 16, 20, 21, which can realize two speed ranges for the drive shaft 2. Alternatively, several switching stages can be implemented.
FIG. 8 shows the speed and power parameters resulting from FIG. 7. Basically, the representation contains two maps - each of which is similar to Fig. 6, but with smaller working speed range for the work machine 1. By the two-stage variable speed 16, 20, 21, these maps are offset from each other, which at the same, total working speed range for Pump ("pump speed" 684-100%) is comparable to Fig. 6 smaller size for the differential drive 5 is required. In addition, you can operate the differential drive 5 in the field weakening area in the map with smaller system performance, since the torque required for the Differenzialsy3tem is basically smaller than its rated torque. Thus, the working speed range in the map with the smaller system power is greater than that for the second map. The two characteristic maps preferably overlap in the hysteresis range "H" in order to avoid frequent switching between the characteristic diagrams. The hysteresis range "H &quot; However, at the expense of a performance even smaller differential system and can, if no overlap of the two maps is required to be smaller or even eliminated.
9 shows an embodiment according to the invention of a differential system with a reduced speed range. Basically, the drive train is the same structure as already shown in Fig. 5. In the power system 29 of the work machine 1 (e.g., a pump, a compressor, or a fan), a throttle 22 is integrated thereafter. Thus, the amount funded by the working machine 1 can be throttled, without the speed of the working machine 1 to 17/05/2013 20:05 18 / 39r- | 68 P.019 / 041 20/41 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA S. · ♦ ····································································· . This throttle 22 is usually used in non-variable-speed drives to regulate / control the amount delivered. The throttle 22 may have a variety of embodiments, with a simple flap is a common variant.
Basically, also for the variant likes. Fig. 9, the additional use of a matching gear 10 possible. In addition, a clutch 15 and a synchronization brake 14 between the second drive or the sun gear 9 and the differential drive 5 can be implemented, furthermore, the gear precursor 16 is also not absolutely necessary.
To make the size of the differential drive 5 and the frequency converter 6a, 19 as small as possible, instead of the rectifier 19 and a grid inverter 6b used and thus the system motor (+) and regenerative (-) are operated, resulting in the size of the differential drive 5 significantly reduced. This moves the base speed (point "T") to the middle of the
Working speed range in which the differential drive 5 brakes and thus the differential system, can be operated very efficiently. Small or operationally required flow rate variations (such as in pumps) can be compensated / regulated with the throttle 22.
One way to extend the working speed range for the work machine 1, as well described 2u Fig. 4, the Feld3chwächebereich or the so-called 87Hz characteristic for the operation of the differential drive 5 and the frequency converter 6a, 6b or 19.
FIG. 10 shows the speed and power parameters resulting from FIG. 9. The selected operating range of the differential system thus moves into an area with a high operating frequency distribution ("probability"). As soon as the differential drive 5 reaches the base speed (point "1") as the pump speed decreases, it is preferably slowed down or stopped. An operationally necessary lower flow rate is realized by activation (control / regulation) of the throttle 22. 17/05/2013 20:05 19/39 R168 P.020 / 041 17/05/2013 19:58 +4315264245
BEER & PARTNER PATENTA p. 21/41 «· · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ··· »• 49 ··· *
The speeds of the differential system remain essentially constant.
FIG. 11 shows the possible speed and performance parameters resulting from FIG. 9 (a throttle 22 can be omitted) for a so-called pump turbine. In this application, the system is preferably operated above the basic speed (point "T") by motor (+) and below the basic speed by regenerative (-). In this case, the drive machine 4 operates in generator mode as a connected to the network 12 generator. Due to the power flow reversal of the differential drive (5) remains at a working machine speed below the base speed motor (+). This provides an electrically simple system, which can be realized without a grid-side inverter. However, since below the base speed, the power flows of generator (4) and differential drive (5) are in opposite directions and thus the system efficiency is worse than in purely engine operation, can - if operationally possible - in this mode, in whole or in part, with a fixed speed, i. preferably with stopped differential drive 5, are worked. Ideally, then, the operating points are set so that the pump turbine will have optimum turbine operating mode efficiency at base speed ("T").
FIG. 12 shows a further embodiment of a differential system for an internal combustion engine 23 as an engine. Since the internal combustion engine 23 is not connected to an electrical network, the required energy for the differential drive 5 is taken from the first drive of the differential gear 3, or supplied to this. In this case, two motor-side inverters 6a are connected by means of a DC intermediate circuit and drive a further differential drive 25. This is connected by means of adjustment gear 24 with the first drive of the differential gear 3. The single-stage adjustment gear 24 can also be multi-stage if necessary. Thus, the Energiekrei3lauf is closed and the system can quasi network-independent both regenerative (-) and motor (+) are operated. If the design speeds of Internal Combustion Engine® 22 and Differential Drive 25 are well matched, the adjustment gears may change
BEER & PARTNER PATENTA P. 22/41
omitted and the differential drive 25 is coupled directly (by means of coupling) to the internal combustion engine 23.
Ideally, the electrical part of the differential system, consisting of differential drives 5 and 25 and the two inverters 6a, also connected to a network. Thus, for example, the starting scenarios described with reference to Figures 1 to 3 can be easily implemented and / or (as is customary, for example, in marine propulsion systems) be supplied with a power supply. In addition, the integration of a switching stage according to FIG. 7 is also possible.
Instead of the differential drives 5 and 25 and the two inverters 6a and a hydrostatic adjusting gear can be used. In this case, the differential drives 5 and 25 are replaced by a hydrostatic pump / motor combination, which are connected to a pressure line and which both are preferably adjustable in the flow volume. Thus, as in the case of a variable speed electric differential drive, the speeds are adjustable. This also applies to applications with an electric machine as the drive machine (4).
The for the operation of an internal combustion engine 23 in combination with a. Differential system resulting significant advantages are on the one hand, the realizable high starting torque and that the internal combustion engine can be driven in an optimal efficiency range, as soon as the differential system · takes over the speed adjustment for the working machine 1. The fact that an internal combustion engine, in contrast to a grid-connected three-phase machine can be operated variable speed, results in a wide range of ways the system, maps expand / vary.
In Fig. 13, a control system for damping driveline vibrations is shown. The torque at the differential drive 5 is proportional to, torque throughout the driveline, creating a
DrehmomentregelungZ control or also a driveline steam by the differential drive 5 is possible. The term "driveline damping" is understood here to mean the targeted regulation of rotational P.022 / 041 17/05/2013 20:06 23/41 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA S. υ ··· ··· · · 0000 · 0 0 ······································································································································································································································ 00 0
Driveline vibrations (Arbeltsmaschienel, drive shaft 2, differential gear 3, prime mover 4 and differential drive 5), which can occur constantly or bnansient and lead to undesirable loads throughout or in parts of the drive train. This is achieved by a modulation of the torque and / or the speed of the differential drive 5 with vibrations of the same frequency.
Such, unwanted driveline vibrations or transient driveline loads can either be caused by externally applied loads on the work machine 1, in the drive shaft 2, the differential gear 3 and the differential drive 5 itself or by the prime mover 4 and are typically visible in the speed or torque behavior of the drive train ,
Preferably, these can by speed and / or
Vibration measurements in the drive train or by current measurements on the drive machine 4 and / or the differential drive 5 are detected. A direct detection of torques is also possible, but usually only costly feasible. The type of detection, however, always depends on where in the drive train, the damping is to be done and whether couplings can be knocked out.
If driveline vibrations are e.g. caused by a typical operating behavior of the working machine 1, and should be compensated in their action on the prime mover 4, these can be reduced or canceled by impressing antiphase torque oscillations at the differential drive 5. This is e.g. in the case of compressors in which it comes at a revolution of the piston rod to design-specific vibration excitations, which correlate strongly with the piston position. Since the respective vibration excitation always occurs at the same piston position, it is sufficient to the circumferential position or rotational position, for example. know by measurement in order to compensate for them. The knowledge of this vibration excitation allows the selective compensation of single or multiple oscillations simultaneously. This is preferably achieved by position detection of the piston rod or by one of the above-mentioned methods. The necessary synchronous and antiphase 17/05/2013 20:07 2, / 39R168 P.023 / 041 17/05/2013 19:58 +4315284245
BEER & PARTNER PATENTA p. 24/41 9 9 9 9 • · · ♦ · 9 ·· * ·· »♦ 9 9 999
• 99 9 9999 9 9 9 9 9 9
Torque / speed adaptation is realized by conventional methods of signal processing, preferably with oscillators and notch filter algorithms, which simulate and evaluate the measured vibration excitation at the correct frequencies. Integrated in a counter-coupled system, this automatically sets the necessary amplitudes and phase positions for the vibrations generated for compensation, with which the actuator on the differential drive 5 is then activated.
As shown by way of example in FIG. 13, a comparison circuit 30 is supplied with a constant rotational speed n "of the prime mover which achieves 2u and with the rotational speed n2 of the drive shaft 2 on the one hand. A control device 31 controls based on the determined therefrom desired speed n5gew0nBCht and the actual speed n5 of the input shaft of the differential drive 5 via the frequency converter 6, the differential drive 5 such that vibrations of the prime mover 4 are as good as desired or desired damped. The driveline damping described with reference to FIG. 13 can also be used independently of all the other embodiments described above. 17/05/2013 20:07 23/39 Ri 68 P.024 / 041

权利要求:
Claims (7)
[1]
17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA p. 25/41 ♦ · · · «« · · | ♦ ·········································································································································································································································· with a drive shaft (2), one connected to a power grid (12) electric drive machine (4) and with a differential gear (3) with three inputs or outputs, wherein an output to the drive shaft (2), a drive to the prime mover (4) and a second drive with a differential drive (5) is connected, characterized in that the differential drive (5) is operated only by motor, while the drive machine (4) is operated by a motor.
[2]
2. The method according to claim 1, characterized in that the differential drive (5) is operated only by motor, while the drive machine (4) is operated by a motor or generator.
[3]
3. The method according to claim 1 or 2, characterized in that a first speed-stable operating point is zero at a speed of the second drive.
[4]
4. The method according to claim 3, characterized in that a further dreh2a, bistable operating point at a rotational speed of the drive machine (4), in which this is connected to the, network (12).
[5]
5. The method according to claim 4, characterized in that the transmission ratio of the differential gear (3) at the further speed-stable operating point is equal to 1.
[6]
6. The method according to any one of claims 1 to 5, characterized in that with the drive shaft (2) a ArbeitsmasChine (1) is connected and that a part of the working power of the working machine (1) by a throttle (22) is destroyed. 7. A method according to claim 4, characterized in that the transmission ratio of the differential gear (3) with the differential drive (5) is set to 1 and held. 17/05/2013 20:07 24 / 39R168 P.025 / 041 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA p. 26/41 • ······· • · I · »o · · · · · E · o

8. 9. 10. 11. 12. 13. 14. The method according to any one of claims 1 to 7, characterized in that the differential drive (5) can be operated with a 87Hz characteristic. Method according to one of claims 1 to 8, characterized in that the differential drive (5) can be operated in the field weakening range. Drive train with a drive shaft (2), one connected to a power grid (12) electric drive machine (4) and with a differential gear (3) with three inputs or outputs, with an output to the drive shaft (2), a drive with the Drive unit (4) and a second drive with an electric differential drive (5) is connected, characterized in that the differential drive (5) via a rectifier (19) to the power grid (12) is connected. Drive train according to claim 10, characterized in that the working machine (1) is a pump, a compressor, a fan, a mill or a pump turbine. Drive train according to claim 10 or 11, characterized in that the drive machine is an internal combustion engine. Drive train according to one of Claims 10 to 12, characterized in that the differential drive (5) is a three-phase machine. Drive train according to one of claims 10 to 13, characterized in that the differential drive (5) via a matching gear stage (10) is connected to the second drive drive train according to one of claims 10 to 14, characterized in that between the working machine (1) and the Differential gear (3) an adjusting (16, 20, 21) is arranged. 17/05/2013 20:08 25 / 39R168 P.026 / 041 15. 17/05/2013 19:58 +4315264245 BEER & PARTNER PATENTA P. 27/41 ♦ ··· «· · · · · ♦ • ♦ · • ♦ · · · ···
[7]
16. Driveline according to one of claims 10 to 15, characterized in that with the drive shaft (2) a working machine (1) is connected and that the working machine (1) is a conveyor in a line system, (29) and that in the line system ( 29) after the working machine (1) a throttle (22) is arranged. 17/05/2013 20:08 26 / 39R168 P.027 / 041

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WO2014183138A1|2014-11-20|

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CN105264266A|2016-01-20|

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EP2997284A1|2016-03-23|

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AT514281A3|2015-10-15|

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PL2997284T3|2021-10-25|

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US10082194B2|2018-09-25|

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA419/2013A|AT514281A3|2013-05-17|2013-05-17|Method of operating a drive train and drive train|ATA419/2013A| AT514281A3|2013-05-17|2013-05-17|Method of operating a drive train and drive train|

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US14/891,892| US10082194B2|2013-05-17|2013-12-30|Method for operating a drive train, and drive train|

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PL13829032T| PL2997284T3|2013-05-17|2013-12-30|Method for operating a drive train, and drive train|

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PCT/AT2013/000218| WO2014183138A1|2013-05-17|2013-12-30|Method for operating a drive train, and drive train|

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EP13829032.5A| EP2997284B1|2013-05-17|2013-12-30|Method for operating a drive train, and drive train|

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CN201480028608.3A| CN105264266A|2013-05-17|2014-05-19|Method for operating a drive train, and drive train|