WO2011098986A2 - Fahrzeugantrieb - Google Patents
Fahrzeugantrieb Download PDFInfo
- Publication number
- WO2011098986A2 WO2011098986A2 PCT/IB2011/050605 IB2011050605W WO2011098986A2 WO 2011098986 A2 WO2011098986 A2 WO 2011098986A2 IB 2011050605 W IB2011050605 W IB 2011050605W WO 2011098986 A2 WO2011098986 A2 WO 2011098986A2
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- WIPO (PCT)
- Prior art keywords
- rotor
- air gap
- stator
- windings
- shows
- Prior art date
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K19/00—Synchronous motors or generators
- H02K19/02—Synchronous motors
- H02K19/10—Synchronous motors for multi-phase current
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K1/00—Details of the magnetic circuit
- H02K1/06—Details of the magnetic circuit characterised by the shape, form or construction
- H02K1/22—Rotating parts of the magnetic circuit
- H02K1/24—Rotor cores with salient poles ; Variable reluctance rotors
- H02K1/243—Rotor cores with salient poles ; Variable reluctance rotors of the claw-pole type
Definitions
- the invention relates to a Vehicle drive, in particular with a synchronous machine.
- the object of the invention is thus, a To provide synchronous machine that works as efficiently as possible.
- An energy source is used to provide electrical energy.
- One powered by the power source Synchronous motor has a rotor and a stator.
- Rotor includes rotor windings for generating a magnetic field at electrical current through the rotor windings.
- the Stator has stator windings for generating a Magnetic field with electric current through the Stator windings on.
- a drive circuit is used for Adjusting the current through the rotor windings in Dependence of the current through the stator windings in such a way that, at least in a speed range, the current through the stator windings increase the speed of the Synchronous motor is reduced.
- the rotor has a magnetizable first body, a magnetizable second body, a magnetizable third body, a first magnetizing element and a second one Magnetizing element on.
- the first body and the second Body extend radially such that the first Magnetizing element in the axial direction between the second body and the first body for magnetizing the first body and the second body is arranged.
- Of the first body and third body extend radially such that the second magnetizing element in the axial Direction between the third body and the first body for magnetizing the first body and the third Body is arranged, with air gap surfaces of the first body, second body and third Body for conducting magnetic flux through the body Air gap are provided to the stator.
- this electric motor as Drive for a vehicle has the advantage that the electricity through the rotor windings depending on the speed can be adjusted. At higher speeds, the Current through the rotor windings decreases, causing the described series closure characteristic arises. moreover allows the geometry of the first body, the second Body and the third body that enough magnetizable material is available to the conduct magnetic flux through the air gap, without that it prematurely saturates in the magnetizable Material is coming.
- the moment is from the current and the achievable dependent on magnetic flux and therefore increase the Moment-related losses at constant flux square with the flow. If you were to use the river with the same current, which also flows in the stator, this would give the Known closed loop characteristics of DC machine, which is very suitable for vehicle drives having advantageous torque / speed characteristic.
- the current now also contributes quadratically to the moment, Now the moment losses no longer rise quadratically for the moment, but only linear, which is a clear one Raising the efficiency curve in the lower Speed range corresponds.
- Permanent magnets in particular those with a particularly high bred river density, have a very early onset of degradation, already at Temperatures of 150 ° C begins. The modulation and thermal limit load is thus lower and very much more effort must be invested in additional cooling.
- a permanent magnet can be in his Field strength only by additionally introduced Reactive power, but in the real resistance of the Motor generates significant losses of effect, weaken. These under the name field weakening or z.T. also early ignition Known method allows a change in the Magnetic strength by phase shift of the armature currents without greater efficiency loss only by about 10%.
- the workspace is compared to conventional increased permanent magnet synchronous machines and the Temperature range in which the motor is driven can, gets bigger.
- Permanent magnets can usually only operated in ambient temperatures up to 150 degrees Celsius become.
- the use of the rotor windings instead of the Permanent magnets extend the temperature range in which the synchronous motor can be used.
- a electrical line provided the first Rotor windings with the second rotor windings connects.
- the electrical line passes through a Conduit of the first body and the axis of rotation passes through the duct.
- Touch becomes a homogeneous magnetic field through the second Body and the third body provided.
- the Air gap surfaces of the first body, the second Body and the third body each in the form of Wall segments formed of circular cylinders, wherein the Wall segments are bounded by four lines each, in each case two of these lines are parallel to each other and the other lines are at right angles to each other , This causes a possible in the air gap homogeneous magnetic field between rotor and stator is generated.
- the machine has a rotor which in comparison to a conventional claw-pole runner two Magnetizing elements and two bodies in the be magnetized second polarization direction, contains.
- At least another air gap between the second body and the Stator provided, the second body and the third Body each at least one further air gap surface for conducting a magnetic flux in the radial direction have through the further air gap. This will be the to Available space exploited because of the air gap widened compared to a pure axial flow machine. Due to the wider air gap, a larger Torque generated.
- the rotor has a magnetizable first body, a magnetizable second body, a magnetizable third body, a first Magnetizing element and a second Magnetizing element on.
- the first body and the second body extend radially such that the first Magnetizing element in the axial direction between the second body and the first body for magnetizing the second body and the first body is arranged.
- the first body and third body extend radially such that the second magnetizing element in the axial Direction between the third body and the first body for magnetizing the third body and the first Body is arranged.
- the first body has at least one Air gap surface on which the stator for conducting a magnetic flux of a first polarization direction through the air gap.
- the second body and the third body each have at least one Air gap surface on which the stator for conducting a magnetic flux of a second polarization direction through the air gap.
- the first magnetizing element and the second magnetization elements have rotor windings, which run concentrically around the axis of rotation. she but also have a permanent magnetic Disc on, with the North Pole and the South Pole of the disc are arranged one behind the other in the axial direction.
- the magnetization elements provide a Whole excitation ready, whose magnetic flux density itself from the excitement of the permanent magnetic Disc can be provided, and out of excitement, the is generated by the rotor windings composed. Consequently becomes a basic need for arousal from the provided with permanent magnetic discs, without it requires an electric current for this purpose. Should the magnetic field strength can be additionally increased Current passed through the rotor windings. This can be on Speed changes are reacted. The magnetic Field strength can also be compared to that of the permanent magnetic discs generated field strength be reduced. This can be done by the Rotor windings are energized so that by the Rotor windings caused arousal of the excitation by the counteracts permanent magnetic disks.
- the magnetic flux through the first body immediately in the radial direction to the outside be guided.
- the direct path to the outside is one broad and not supersaturated track for the magnetic River ready.
- For the second Body and the third body must be the flow of, radial considered from outside the magnetization elements to the Air gap surfaces are brought. This is with a Direction change of the field lines connected, but the necessary magnetic flux is on two bodies split, so that too the risk of magnetic Saturation of the second and third body is encountered.
- the maximum speed is determined by the excitation of the rotor limited.
- the permanent magnet generates a magnetic field in the Rotor, which interacts with the magnetic field in the stator and necessary for driving the engine.
- the magnetic field generated by the permanent magnet Counterinduction in the stator windings It will be a Voltage generated by the flow of current through the Counteracts stator windings.
- the counterinduction is depending on the speed of the rotor. The faster the rotor rotates, the larger is the induced in the stator Tension.
- the stator windings are driven by a driver energized. At some point, that is due to the mutual induction generated voltage so large that the driver for the Stator windings comes to its limit. Thus, off a certain speed the speed due to Counterinduction can not be further increased.
- the permanent magnetic discs Provide a minimum of excitement.
- Permanent magnets can generally have relatively high field strengths in a relatively small volume and at a relatively small Weight of the discs are generated in the rotor.
- the excitement over that of the Permanent magnet provided excitation can be increased can. It is also possible with the help of the rotor windings the excitation smaller than from the permanent magnets to stop the excitation.
- a electrical line provided the first Rotor windings with the second rotor windings connects with each other.
- the electrical runs Conduction through a duct of the first body and the axis of rotation passes through the duct. Consequently becomes as short a path as possible for the electrical line provided what the electrical resistance and thus minimizes power loss. Besides, it leaves enough Place outside the axis of rotation, so that there can flow through magnetic flux.
- Touch becomes a homogeneous magnetic field through the second Body and the third body provided.
- the Air gap surfaces of the first body, the second Body and the third body each in the form of Wall segments formed from circular cylinders. This causes, that in the air gap as homogeneous as possible magnetic field is generated between the rotor and the stator.
- It according to another aspect of Registration will be an electric machine with a rotor and a stator, wherein the rotor rotor windings and a claw pole provided.
- the claw pole becomes a magnetic field generated by the rotor windings magnetized and has a variety of claw pole teeth on.
- the claw pole teeth each have one Air gap surface, along an air gap between Rotor and stator runs on.
- the claw pole teeth also contain a substantially perpendicular to Air gap surface running claw sidewall for conducting the magnetic flux to the air gap surface.
- the Cross-sectional area of the field traversed by the magnetic field Claw pole neck is at least half as large as the area the air gap surface.
- the ratio of the areas ensures that the magnetic field lines are particularly effective to the Air gap surface can be passed. Is to necessary that the claw pole neck is thick enough to one To produce optimum magnetic flux density in the air gap. in the In the prior art, the claw pole necks become thin performed, which limits the strength of the magnetic flux density. However, it is especially at Klauenpolen, which, as in present case, in the high power range advantageous can be used that the current through the Rotor windings is as low as possible. This is necessary to the abrasion, for example by sliding contacts between the Rotor and the connection for the rotor current outside the Rotor as little as possible to load.
- the cross-sectional area of the claw pole neck, which is traversed by the magnetic field at least 0.6 times as large as the area of Air gap surface.
- This scale has become as proved to be advantageous over the factor 0.5 because This increases the magnetic flux density in the air gap.
- the Rotor windings in the circumferential direction for generating a Total excitement This makes it possible with as possible few rotor windings to get along, however, over run a long distance, what the homogeneity of the Magnetic field increases.
- stator has a frame on the transformers are fixed, the Transformers before assembly with the rotor with each other be fixed so that they then together with the Rotor are connected.
- Another aspect of the application relates to an electric machine with a stator and a rotor arranged rotatably about a rotation axis is and the rotor windings for generating a Magnetic field in the rotor has, as well as an air gap between stator and rotor.
- An electric Connecting arrangement between the stator and the rotor has the following:
- This connector ensures that the Connector has as little abrasion as possible, since the circumference of the Connector and thus the area where friction occurs is small. Thus, a long life of the Connector enabled.
- an electric machine with a stator and a Rotor, which is provided rotatably about an axis of rotation, and a first air gap and a second air gap provided between stator and rotor.
- the rotor points a magnetizable first body, a magnetizable one second body, a magnetizable third body, a first magnetizing element and a second one Magnetizing element on.
- the first body and the second body extend radially such that the first Magnetizing element in the axial direction between the second body and the first body for magnetizing the first body with a first polarization direction and of the second body with a second one Polarization direction is arranged.
- the first body and the third body extend radially so that the second magnetizing element in the axial direction between the third body and the first body for magnetizing of the first body with the first polarization direction and of the third body with the second polarization direction is arranged.
- the first body and the second body each have at least one air gap surface, passing through the stator to conduct a magnetic flux the first air gap is opposite.
- the third body also has at least one air gap surface, the the stator for conducting a magnetic flux in Axial direction through the air gap is opposite.
- the electric machine is fine assemble. Due to the fact that the air gaps in radial Outward direction, after assembly of the rotor Stator be introduced from the outside. This simplifies the Mounting opposite machines where the stator is between Parts of the rotor must be inserted.
- At least another air gap between the second body and the stator is provided, wherein the second body and the third body in each case at least one more Air gap surface for conducting a magnetic flux in Have radial direction through the other air gap.
- stator has a variety of Transformers, each one a transformer core and Contains stator windings, these may have Transformers individually mounted and then in the Machine be used. The individual transformers to wind can be easily automated.
- stator has a frame on the transformers are fixed, the Transformers before assembly with the rotor with each other be fixed so that they then together with the Rotor are connected.
- FIG. 1 shows a block diagram of Connection of a drive motor for a vehicle in a series connection circuit
- Figure 2 shows an embodiment of the Wiring of a drive motor for a vehicle, wherein the Drive motor is a synchronous machine and the Magnetization of the rotor is powered by the total current;
- FIG. 3 shows a further one Embodiment of the wiring of a drive for a vehicle
- FIG. 4 shows the efficiency of a permanent magnet synchronous motor above the speed
- FIG. 5 shows the efficiency of a Synchronous motor over the speed at speed-dependent varying excitement
- FIG. 6 shows a first course of the Rotor current above the speed of the synchronous motor
- FIG. 7 shows a second course of the Rotor current above the speed of the synchronous motor
- FIG. 8 shows the course of the torque above the speed
- FIG. 9 shows an oblique view an electric motor
- FIG. 10 shows a cross section through the electric motor
- FIG. 11 shows a further cross section through the electric motor
- FIG. 12 shows a further cross section through the electric motor
- Figure 13 shows a plan view of the Electric motor with housing removed
- Figure 14 shows a plan view of the Electric motor with housing removed and stator windings removed
- Figure 15 shows a plan view of the Rotor of the electric motor
- Figure 16 shows a plan view of the Rotor with rotor lid removed
- Figure 17 shows a plan view of the Rotor for partially removed components
- FIG. 18 shows another plan view on the rotor with partially removed components
- Figure 19 shows a plan view of the Rotor for partially removed components
- Figure 20 shows a section through a Synchronous motor with permanent magnetic excitation
- FIG. 21 shows a claw pole rotor of FIG another synchronous motor with current excitation instead of Magnetic disk excitation from FIG. 20;
- Figure 22 shows claw pole rotor with a Combination of permanent excitation and current excitation
- FIG. 23 shows a partial section through the synchronous motor of Figure 9
- Figure 24 shows a connector for electrically contacting the rotor in a sectional view
- Figure 25 shows the connector FIG. 24 shows a further sectional view
- Figure 26 shows a part of one in one Synchronous motor used claw pole in three views
- Figure 27 shows part of another Claw pole in three views
- FIG. 28 shows a second one Embodiment of a synchronous motor with Claw pole magnetization as Axialhneaus arrangement with partial use of the claw pole lateral surfaces in three different views;
- Figure 29 shows a part of a first one Body of the synchronous motor of Figure 28;
- Figure 30 shows the assembly of a Part of the Axialklauenpols with the first body of Synchronous motor of Figure 28;
- Figure 31 shows a second body the synchronous motor of Figure 26
- FIG. 32 shows the second body in FIG another view
- Figure 33 shows the second body and the third body of the synchronous motor of Figure 28;
- FIG. 34 shows the rotor of FIG Synchronous motor of Figure 28
- FIG. 35 shows a detail of FIG Rotor of Figure 34
- FIG. 36 shows the detail from FIG 35 with a part of the stator as a standard transformer core
- Figure 37 shows transformer cores of the stator
- Figure 38 shows transformers of Stators with stator windings
- Figure 39 shows the stator of the synchronous motor
- Figure 40 shows the parts of the rotor and the stator
- FIG. 41 shows further parts of the Synchronous motor in a plan view
- Figure 42 shows yet another Top view of the synchronous motor
- Figure 43 shows a section through the Synchronous motor of Figure 28.
- Figure 44 shows a section through a Synchronous motor according to another embodiment
- Figure 45 shows a section through a Synchronous motor according to another embodiment
- Figure 46 shows another Embodiment of a rotor with claw poles
- Figure 47 shows a section through the Claws of the rotor of Figure 46;
- Figure 48 is a view of the claw pole Fig. 46;
- FIG. 49 shows the claw pole from FIG 46 and 48 in section
- FIG. 50 shows the claw pole from FIG 46 and 48 in a further sectional view
- Figure 51 shows another Embodiment of a rotor with claw poles
- FIG. 52 shows the claw pole from FIG 51 on average
- FIG. 53 shows a vehicle with a drive motor.
- FIG. 1 shows a first one Block diagram for a drive 2 for a in the figure not shown land vehicle.
- the schematic diagram shows a power source 7, a resistor 4, a Electric motor 1 and a coil 3. From the power source 7 An electrical voltage U is provided.
- One first terminal 70 of the power source 7 is connected to a first terminal of the first resistor 4, whose second port with a first port 600 of a Rotor 11 is connected, while the second port 601 of the rotor 11 with a first connection of the coil 3 connected is.
- the second terminal of the coil 3 is connected to the second terminal 71 of the power source 7 connected.
- the circuit diagram of Figure 1 sets Replacement circuit diagram for the drive with the help of a Electric motor is.
- This electric motor is as a Synchronous machine, which has a stator with stator windings and having a rotor with rotor windings executed.
- the stator generates a magnetic field in which the rotor, which also generates a magnetic field, moves. This will generates a torque that drives wheels of the vehicle.
- the terminals 600 and 601 of Electric motors 1 are the connections for the Rotor windings, the resistor 4 provides the resistance of the rotor.
- the coil 3 symbolizes the inductance the windings of the stator, the stator windings.
- FIG. 1 symbolizes that the stator and the rotor in series are connected, analogous to a series connection of a DC machine.
- FIG. 2 shows another Block diagram for the wiring of a drive for a vehicle.
- an energy source 7 here a capacitor connected to its two terminals 70 and 71 provides a DC voltage U.
- the drive points furthermore an electric motor 1, an inverter 8 and a further capacitor 9, whose first electrode with connected to the terminal 71, on.
- the terminal 70 is with a first terminal 131 of a rotor 11 of the Electric motor 1 connected.
- the rotor 11 is within a stator 12 of the electric motor 1, it is thus an internal rotor machine.
- the second port 132 of the rotor 11 is connected to a first terminal of the Inverter 8 connected.
- a second electrode of the Condenser 9 and a second terminal of the inverter. 8 are connected to the second terminal 71 of the power source 7th connected.
- Three outputs of the inverter 8 are over three-core connection cable 14 with three stator windings the stator 12 of the electric motor 1 is connected.
- the current through the rotor windings is in the Inverter 8 fed.
- the Inverter 8 as is formed three-phase inverter, the Current converted into three alternating currents, respectively mutually phase-shifted by 120 degrees.
- everyone who Alternating currents will be in one of three stator windings fed, with stator windings coming from different Phases of alternating currents are fed, from each other are electrically isolated.
- This induced voltage causes the effectively applied voltage across the stator windings is reduced, whereby the amount of electricity through the Stator windings decreases. This decreases due to the Series connection but also the current through the rotor windings.
- the rotor windings are thus connected in series with the inverter 8, so that the current I S flowing through the rotor windings also flows through the inverter 8.
- the circuit diagram of Figure 2 thus shows a realization of the block diagram of Figure 1.
- FIG. 3 shows another one Embodiment of the wiring of a drive for a in the figure not shown vehicle. Shown is again an energy source, here a battery 5, at its two Terminals 70 and 71 provides a DC voltage U.
- the drive further comprises an electric motor 1, a Inverter 8, a transmitter 16 and another capacitor 9 on.
- the terminal 70 is connected to a first terminal of the Gebers 16 connected, whose second connection with a first rotor terminal 13 of the rotor 11 is connected. Of the second rotor terminal 13 of the rotor 11 is connected to the ground 33 connected.
- the terminal 70 is also equipped with a first electrode of the capacitor 9 and at the same time with a first connection of the inverter 8 connected.
- the second Electrode of the capacitor 9 and a second terminal of the Inverter 8 are connected to the second terminal 71 of the battery 5 connected.
- Three outputs of the inverter 8 are over three-core connection cable 14 with stator windings of the Stators 12 of the electric motor connected.
- the encoder 16 is a power source, the is adjusted so that the current through the encoder 16 is dependent on the rotational speed of the electric motor 1. at high speeds increases due to the mutual inductions the Voltage from the inverter 8 to the stator windings must be created. To counter this, reduced the encoder 16 accordingly with increasing speed the Current through the rotor 11.
- the induced in the stator windings Voltage increases linearly with the speed.
- the rotor current is adjusted so that it is linear with the Speed decreases. From a certain speed decreases in an embodiment of the rotor current but not from, but is left constant from this speed, so the magnetic flux generated in the rotor is a minimum strength not below.
- FIG. 4 shows the efficiency, shown above the speed at permanently excited Synchronous machines.
- the efficiency also efficiency called, the synchronous machine rises from a value of zero steady at zero speed, reaches one Maximum value, for example at 3500 revolutions per Minute, and then decreases again.
- the operating current the machine (DC in front of the inverter of the Synchronous machine) the excitation forming DC form the claw pole, which means the said Series closure characteristics achieved.
- Figure 5 shows the efficiency over the Speed in synchronous machines with varying excitation.
- the solid lines show the efficiency of the Synchronous machine over the speed.
- the different ones Solid lines show the efficiency different levels of excitement. This can ever be after excitation different machine characteristics always with a high Efficiency work.
- FIG. 6 shows a profile of the current I R through the rotor windings versus the rotational speed. This course is predetermined by the encoder 16 from FIG.
- the maximum current through the rotor windings is 2 A.
- a current of 2A is impressed into the rotor.
- the rotor current drops above the revolutions in the form of a hyperbola of the form const / x.
- the current is set to the constant value of 0.4A. The fact that the current through the rotor is not further lowered, a minimum level of excitation in the engine is ensured even at high speeds.
- Figure 7 shows a further course of the current I R over the speed n.
- the maximum value of 2A is set at the speed of N. From the speed 0, the current in the form of a hyperbola drops to the minimum value of 0.35 A at 3000 rpm. For frequencies greater than 3500 rpm, the minimum value of 0.35 A is set for the rotor current.
- FIGS 6 and 7 show Embodiments for the rotor current.
- the rotor currents can take on more progress, common to them, that at least in a speed range of the current through the Rotor windings decrease with increasing speed.
- FIG. 8 shows a torque curve above the speed.
- the torque drops above the speed hyperbolic off.
- the power output by the engine is equal to the product of torque and speed.
- Target of Adjusting the rotor current is that the power over the Speed is constant.
- the power of the engine corresponds a rectangular area passing through the coordinate axes and bounded by straight lines through a point on the curve becomes. Is the area equal under all points of the curve? big, so the performance is the same for all speeds.
- Figure 9 shows a plan view obliquely from on top of an electric motor 1 in a first Embodiment.
- the housing upper side 20 has cooling ribs 22.
- Housing bottom 21 and housing top 20 are respectively shaped like a lid, with the openings of the two lids touch.
- In the common interior of Housing top 20 and housing bottom 21 are a rotor and a stator housed.
- FIG. 10 shows a section through the Electric motor, where the cut is not through the central axis of the engine, but at a distance of about 5% of the Radius from the axis of rotation 90 perpendicular from the line A-A in Figure 9 is performed.
- FIG. 10 is shown in FIG the rotation axis 90 is vertical.
- the radial Direction r thus runs vertically, the axial direction a horizontally and the circumferential direction u points out of the sheet out.
- stator 12 and the rotor 11 are enclosed by the housing 19 .
- stator laminations 27 are in one Recess 200 of the housing top 20 and in a Recess 210 of the housing bottom 21 inserted.
- To close inside stator windings 24, which in the Figure are shown as a continuous metal, in fact but from a multitude of parallel lines going into the Insert sheet, insist.
- the Stator 12 from the rotor 11 separates.
- the air gap 28 is only on the right side and there only partially to recognize otherwise it is of components of the rotor 11 or the Stators 12 hidden.
- the thickness of the air gap 28 depends among other things on whether the stator windings 24 the Rotor 11 are directly opposite or whether between Stator windings 24 and the rotor 11 still parts of Stator laminations 27 are provided. In that in this Figure shown section are located between Stator windings 24 and the rotor 11 no parts of the Stator laminations 27.
- the rotor 11 has a north system 30, a magnetizable first body 40, too South system is called, first rotor windings 510 and second rotor windings 520, two rotor covers 36 and Screw connections 57 on.
- the north system 30 denotes the whole of a second body 31 and a third body 32.
- the first body 40, the second body 31 and the third body 32 each extend from the right side of the stator 12 to the left shown side of the stator 12.
- the North System 30 is as above indicated, from a magnetizable second body 31st and a magnetizable third body 32, the second body 31 above and third body 32 below are provided. Both, the first body 31 and the second Body 32 each contain a vertical extending side wall 33, a claw neck 34 and a Claw top 35.
- the claw top 35 has a the Stator 12 opposite surface, the so called air gap surface 39.
- the side walls 33 and the air-gap surfaces 39 are perpendicular to each other aligned.
- the claw neck 34 forms the connection between a side wall 33 and the claw top 35.
- the second body 31 and the third Body 32 are aligned with each other so that they themselves with their claw tops 35 touch. Thus, will ensured that from the north system 30 uniform Magnet flux lines can be passed through the air gap 28.
- rotor windings 510 and 520 adjoin the side walls 33 in each case.
- the first body 40 then adjoins the rotor windings 510 and 520, which extends in the vertical direction from the first, top-side rotor windings 510 to the second bottom rotor windings 520.
- the rotor windings 510 and 520 are a plurality of rotor windings which are parallel and extend out of the sheet or into the sheet. These are, for example, 100 rotor windings through which the rotor current I R of 1 to 2 A respectively flows.
- the first body 40 consists of a single piece of iron and is shaped to the outside has a plurality of teeth. Those teeth that way southern teeth 41, are extensions of the first Body to the outside. The southern teeth 41 close each with a frontal air gap surface 43 from.
- the electric motor becomes special effective when the magnetic flux density in the air gap 28 so big as possible.
- the rotor covers 36 close the rotor up and down. Screw connections 57 run from top to bottom through the entire rotor 11, so that Screw the screw connections 57 through the top Rotor cover 36, the second body 31, the third body 32nd and the lower rotor cover 36. When putting on the Screw 57, the rotor cover 36, the second body 31 and the third body 32, the Rotor windings 510 and 520 and the first body 40th pressed against each other, making them against each other are immovable.
- a duct 54th provided through which electrical lines run, the transport the current to and from the rotor windings 510.
- the duct 54 terminates at the top in the upper rotor cover 36 and runs down through the bottom 56 of the Housing bottom 21.
- a connector 55 is provided via the electrical lines through the duct 54th electrically connected from outside the electric motor can be.
- the stator 12 closes at the top with an im essentially circular disc-shaped stator cover 60 from.
- This stator cover 60 is with screw connections 61 connected to the stator lamination 27.
- FIG. 11 shows a further section, the starting from the line B-B in Figure 9 vertically the electric motor is guided.
- the distance of the cut to the axis of rotation 90 is approximately in the radial direction one third of the radius. Three of the stator windings 24 are completely in section to see.
- FIG. 12 shows another one Sectional view through the electric motor.
- the cut is compared to Figure 10 closer to the axis of rotation 90th guided.
- FIG. 12 more sectional area of the To see stator laminations 27, since the cut surfaces of the Stator windings 24 lie further inside.
- This implementation 51 is perpendicular to the upper rotor cover 36 to the lower rotor cover 36.
- the rotor 11 contains eight Screw connections 57, which extend beyond the circumference of the rotor 11 are distributed.
- FIG. 13 shows an oblique view the electric motor with the housing removed.
- the Stator laminated core 27 is shaped as a ring and around the rotor 11 provided.
- In the stator lamination 27 are respectively Openings 241 that receive the stator windings 24, intended.
- the openings 241 are in the circumferential direction distributed.
- the openings form in the stator lamination packet 27 vertical recesses.
- the stator windings 24 consist of several loops 240 of stator windings 24, wherein each loop 240 passes through two adjacent openings runs and below and above the stator lamination 27 is closed.
- FIG. 14 shows the electric motor in one Oblique top view with removed housing, wherein in Compared to Figure 13, the loops are removed. It is recognizable that the openings 241 to the Air gap surface 39 and 43 range.
- the rotor cover 36 has at its edge a plurality of recesses 360. There, where no recesses 360 are present, respectively attached upper parts of the screw 57.
- Slip rings 500 are provided, over which the current flows from the outside is impressed in the rotor windings.
- a bearing 85 Above the Slip rings 500 is a bearing 85, with the Rotor is stored in the housing.
- FIG. 15 shows an oblique view the rotor 11. To recognize the southern teeth 41 and the Claw tops 35 in alternation.
- FIG. 16 shows in a top view the Rotor.
- the rotor lid 36 removed.
- the second body 31 includes the side wall 33, the claw neck 34 and the Claw top 35.
- the claw top 35 of the second Body 31 and the claw top 35 of the third body 32 touch each other at connection surfaces 355. The For this required contact pressure is with the help of Screw connection 57 guaranteed.
- a first connection cable 602 and a second connection cable 603 pass through the middle of Side wall 33 of the second body 31 and form the electrical connection between the slip rings and the rotor windings.
- FIG. 17 shows the rotor from FIG. 16, wherein the second body 31 is removed.
- first rotor windings 510 in the Top view.
- the connection cable 602 is connected.
- the second end of the Connecting cable 602 is through the duct 54 to the led second rotor windings and is there with a connected to the first end of the second rotor windings.
- the second end of the second rotor windings is through the Conduit 54 led up and there with the Connection cable 603 connected.
- the first rotor windings 510 and the second rotor windings are thus connected in series.
- FIG. 18 shows the rotor from FIG. 16, wherein, compared to FIG. 16, the rotor windings 510 were removed.
- the first Body with its south core 42 and the at the core connected southern teeth 41 to see.
- the air gap surface 39 the Front of the northern teeth, pointing in the direction of the air gap, has an airgap surface that forms a segment a cylinder wall of a circular cylinder. This segment is bounded by four lines, each one two of these lines are parallel to each other and the other lines at right angles to each other.
- the lines are a and c parallel to each other and the lines b and d are to each other parallel. Those lines that are not parallel to each other are perpendicular to each other, so a is vertical on b, a is perpendicular to d, c is perpendicular to b, c is perpendicular to d.
- the second and third bodies are the same. You too are as segments of walls of circular cylinders shaped. The segments are bounded by four lines, each of the lines being parallel to one of the others and the rest of the other lines intersect vertically.
- FIG. 19 shows the rotor from FIG. 16, with the north system completely removed.
- the first body southern teeth 41 and a south core 42 which has a substantially cylindrical Structure has and to which the southern teeth 41 are connected.
- the lines are a and c parallel to each other and the lines b and d are to each other parallel. Those lines that are not parallel to each other are perpendicular to each other, so a is vertical on b, a is perpendicular to d, c is perpendicular to b, c is perpendicular to d.
- the magnetic flux, vertical passes through the air gap surface 43, thus becomes by a substantially rectangular air-gap surface directed.
- the magnetic flux coming from the Stator windings is generated, emerges from the stator also by a substantially rectangular Air gap surface of the stator off. So that's it Magnetic field in the air gap very homogeneous, much more homogeneous than at triangular air gap surfaces of conventional claw poles.
- Electric motor may be mounted as follows. To assemble the rotor is first a second of the two ends of a first Rotor windings 510 from top to bottom through the Conduit 54 of the first body 40 out. Subsequently, the rest of these first rotor windings 510 on the now upper side of the first body 40th placed. Subsequently, the second body 31 is placed on the first body 40 and the first rotor windings 510 placed, with the first of the two ends of the first Rotor windings 510 by means of the duct 54 through the second body 31 is guided. It follows Rotor cover 36 which is placed on the second body 31. The second end of the first rotor windings 510 is connected to the Connection cable 602 connected, which finally with a the slip rings is connected.
- One End of the second rotor windings 520 is connected to the protruding second end of the first rotor windings 510, for example, by soldering, connected.
- the second end the second rotor windings 52 is through the Conduit 54 led, where it later with the Connecting cable 603 will be connected.
- the second Rotor windings 520 are laid on the first body 40. Subsequently, the third body 32 on the first Body 40 and the second rotor windings 520 placed it followed by a rotor cover 36, which on the third body 32nd is placed. In this case, the third body 32 and Rotor cover 36 on the existing screws of the Screwed connection 57 pushed. Subsequently, the Tightened screw 57 and so the rotor 11 is compressed.
- stator 12 is wound and then the rotor 11 is inserted into the stator 12. It will be the connections for the slip rings 500 made and the rotor 11 is in bearings 85 of the Housing top 20 and the housing bottom 21 stored. Finally, housing top 20 and Housing bottom 21 screwed together.
- the electric motor so be dimensioned such that in the air gap one each magnetic flux density of 1 Tesla prevails. It will estimated that to 800 to 1200 Amperewindungen necessary. At currents of 1 A through the Rotor windings 510 and 520 are thus the Rotor windings 510 to 520 each from 400 to 600 turns.
- the engine can be so for example be dimensioned so that the rotor has a diameter of 220 mm and the engine is 100 mm high overall.
- FIG. 20 shows a schematic diagram an example of the excitation of the synchronous motor after an embodiment of a radial flux machine with Permanent excitation.
- a first permanent magnetic Washer 110 is provided between the first body 41 and the second body 31 .
- the permanent magnetic disc 110 is divided into a north pole N and a south pole S.
- the polarization direction in the magnet is axial.
- a second permanent magnetic disk 110 between the first body 40 and third body 32.
- the second permanent magnetic disk 110 is also concentric around the rotation axis 90 is provided and is also in split a north and a south pole.
- the South Pole S points in the direction of the first body 40 and the north pole N in Direction of the third body 32nd
- the permanent magnetic disks 110 polarize the first body with a first Polarization direction and the second body and third Body with a second polarization direction.
- the Polarization causes the magnetic field lines to start from the north pole N initially extend axially outward, after which they are deflected radially outwards in the side wall 33 become.
- the field lines occur at the air gap surfaces 39 substantially perpendicular to these.
- the field lines then pass through the air gap and not shown Stator and occur at the air gap surfaces 43, respectively the first body 40 radially again by subsequently deflected in the axial direction to the outside finally to the South Pole to meet permanent magnetic disks 110.
- the magnetizing elements are as formed axially magnetized magnetic disks whose Magnetization direction are directed opposite to each other. This will be in the first body, also middle stamp called, forced a flux concentration, which then the drives magnetic flux to the corresponding poles.
- Figure 21 illustrates the excitement of Rotor with the help of rotor windings.
- rotor windings 510 Between the first Body 40 and second body 31 are rotor windings 510 provided while rotor windings 520 between the first body 40 and the third body 32 are provided.
- the rotor windings 510 and the rotor windings 520 are energized opposite. In this case, the rotor windings 510 and the rotor windings 520 in series or in parallel be switched.
- the energization of the rotor windings 510 and 520 ensures that the second body 31 and the third body 32 as in FIG. 20 be polarized.
- the field lines enter the second Body 31 and third body 32 initially substantially in the axial direction, are then in the radial direction turned to the outside, finally to the Air gap surfaces 39, the second body 31 and the leave third body 32.
- Simultaneously with the Rotor windings 510 and 520 will also be the Stator windings of the stator energized. This causes that in the laminated stator core also north poles and south poles form. Accordingly, the magnetic flow Field lines through the air gap through the stator lamination back in the rotor.
- stator windings with AC powered change over time North poles and south poles in stator laminations. Are there North poles and south poles of stator laminations and rotor it is due to the attractive and repulsive forces between rotor and stator to one Rotary movement of the rotor.
- the field lines pass through the Air gap surfaces 43 of the first body 40 back in the rotor in a substantially radial direction to then in the axial direction outward to the second body 31st or to the third body 32 to be deflected.
- the first Body 40 thus forms the South Pole, while the second Body 31 and the third body 32 form the north pole.
- the first body is called North pole magnetized while the second body 31 and the third body 33 form the south pole.
- the Rotor windings 510 and 520 are driven so that a current from 2 A flows through it.
- the frequency of the alternating current is thereby continuously from 0 Hz to the desired one AC frequency increased.
- the speed of the engine is equal to the AC frequency times the number of pole pairs.
- the magnetic field generated with the stator windings acts together with the magnetic field generated in the rotor. there it comes to attractive and repulsive forces between Rotor and stator, so that the rotor rotates.
- the from a driver to the Stator windings applied voltages must be at least be as large as the induced voltage. Around induced voltage will not rise too much will at rising speeds, the current through the Rotor windings lowered.
- Figure 22 shows a section through a Synchronous motor in which there is both a permanent excitation as also gives a current excitation.
- They are the permanent magnetic disks 110 between the first body 40 and second body 31 and between first body 40 and third body 32 is provided.
- the rotor 11 contains Rotor windings 510 and 520 as shown in Figure 21. Die Field lines are substantially as in Figures 20 and 21.
- the current through the rotor windings 510 and 520 can be varied so that as needed Total excitation of the motor over that of the permanent magnets provided excitation can be increased or decreased can. Will the direction of the current through the Rotor windings 510 and 520 turned over, the Total excitation smaller than that of the permanent magnets provided excitement.
- FIG. 23 shows a partial section through an embodiment of the rotor 11.
- Axially inside is the first body 40, which has a variety of southern teeth 41 has.
- the second body 31 shown on the left in the figure, and the third Body 32, shown in the figure on the right.
- Between the first Body 40 and second body 31 are the first Rotor windings 510.
- the rotor windings are 510th but spaced from the axis of rotation 90. This means that is located between the rotation axis 90 and the Rotor windings 510 is an area in which the first Body 40 and the second body 31 are immediately adjacent.
- Symmetrical to the first Rotational windings 510 are the second Rotation windings 520 between the first body 40 and the third body 32 is provided.
- the current flow through the first rotor windings 510 and the second rotor windings 520 is in the opposite direction.
- the first Rotational windings 510 and the second rotary windings 520 respectively the first body 40, the second body 31 and magnetize the third body 32 so that the Field lines initially radially inward and then pointing axially outward.
- the first body 40 becomes as the south pole and the second body 31 and the third body 32 magnetized as North Pole.
- the northern teeth 37 and the Southern teeth 41 alternate in the circumferential direction.
- a first connector 80 is from externally inserted into the second body 32 such that the Rotation axis 90 passes through the connector 80.
- a second connector 80 is inserted into the third body 32 introduced such that the rotation axis 90 through Connector 80 runs.
- About the two connectors 80 is Current impressed in the rotor windings 510 and 520.
- the surface on the Friction between a connector 80 and the second body 31 and third body 32 is formed low. Thus comes It reduces wear compared to conventional slip rings.
- Figure 24 shows a cross section through the connector 80, with the rotor windings from the outside can be connected electrically. This is done via a connector 80, which is shown in section in FIG is.
- the connector is rotationally symmetric with respect to a central axis 91 is formed.
- Rotor side is an arrester 84 provided.
- the arrester 84 is part of the rotor and thus moves with the rotor.
- There is also a spring 81 is provided, which is clamped in the arrester 84.
- the Spring 81 is with two upper ends in the arrester 84th clamped while helping with their lower end a ring 82 is clamped together.
- the connector 80 is clamped in the spring 81 and remains stationary in With respect to the stator, while the spring 81 with the Arrester 84 rotates.
- the central axis lies on the Rotation axis of the rotor or in other words is the Connector centered about the rotation axis 90.
- the connector 80 and the spring 81 which conducts the current further to the arrester 84.
- FIG. 25 shows the connector 80 from FIG 24 in another section, with the cutting plane itself located in front of the axis of rotation of the connector 80.
- the Connector 80 has a constriction 8000, to which the Spring 81 is adjusted.
- FIG. 26 shows how the Cross-sectional area is calculated in the north system.
- To is the second body in three different views shown. Above left is a section through the second body shown, wherein through the side wall 33 and the Claw top 35 is cut.
- Top right in figure Fig. 26 is a plan view of the second body, in such a way that the air gap surface 39 is looked.
- Bottom left is a side elevation the second body such that on the side wall 33rd is shown.
- the illustration above left shows the side wall 33, claw neck 34 and claw top 35 in section.
- the length of the air-gap surface 39 is a 1.
- the cross-sectional width e of the claw neck is calculated as the distance between the points P1 and P2.
- the points P1 and P2 of the dog-neck are those points of the surfaces of the dog-neck 34 which are cut by the tangents T1 and T2.
- the tangents T1 and T2 are those which intersect the air-gap surface 39 or its extension and the outer surface 330 or their extension of the side wall 33 at the same angle.
- the Width of the air-gap surface 39 is c1 and the width that of the cross section through the claw neck c2. So that Cross-sectional area through the claw neck 34 is greater than 0.5 times the claw air gap area, must apply:
- Figure 27 shows another Calculation method for the cross-sectional area of the claw neck of the north system.
- the claw neck 34 is at its outer Edge straight flattened at an angle ⁇ of 40 ° opposite the air-gap surface 39. It becomes the point P as P1 selected on the surface of the claw neck as far from the airgap surface as from the Surface 330 of the side wall 33 is removed.
- Figure 28 shows another Embodiment for a synchronous machine.
- the Synchronous machine of this embodiment is as Axialhnemaschine executed while respecting the Figures 9 to 27 described machines Radial flux machines are.
- the machine of Fig. 28 is also as an internal rotor machine with internal rotor 11 and externally located stator 12 is formed. Between the rotor 11 and the stator 12, two air gaps are provided, the spaced apart each other on a plane is perpendicular to the axis of rotation 90 is cut.
- the rotor 11 has a first body 40, a second body 31 and a third body 32 on. These bodies 40, 31 and 32 are respectively constructed rotationally symmetrical to the rotation axis 90. They each have a circular cylindrical core as well outwardly pointing teeth.
- the stator 12 has a Variety of stator windings 24 on, each with transformer cores associated with them transformers form. These are 15 transformers 111, wherein each of the transformers 111 each one Transformer core and stator windings has. The Transformers protrude from the outside in the radial direction in the direction of the axis of rotation 90.
- the teeth of the bodies 31, 32 and 40 are in two spaced-apart parallel planes arranged. There is a free space between these levels provided in which the transformers of the stator 12th are inserted.
- Figure 29 shows a part of the first one Body 40.
- the first body 40 is in this view to Half shown.
- the first body 40 has a South core 42, which has the shape of a circular cylinder. At These are followed radially outward south teeth 41.
- FIG. 30 shows the first body 40 Completely.
- the south core 42 consists of two cylinders, which have the same radius and concentric are arranged adjacent to each other. At each of these Cylinders are each eight south teeth 41 attached.
- the Southern teeth 41 are outward in axial direction offset on the cylinders, so that, radially At the height of the cylinders of the south core 42 no Southern teeth 41 are located.
- FIG. 31 shows the second body 31.
- This has a base plate 101, which has the shape of a Circular cylinder has. Close to the base plate 101 radially outward extensions, called northern teeth 102 on.
- FIG. 32 shows the second body 31 and a permanent magnetic disk 110 in one Top view.
- the permanent magnetic disc 110 mounted for the Excitation of the rotor provides.
- the permanent magnetic Disc 110 consists of two layers, the are polarized differently. The two layers are circular cylindrical shaped and centered around the Rotation axis 90 arranged.
- FIG. 33 shows the second body 31 and the third body 32.
- Second body 31 and third Bodies 32 are each centered about the axis of rotation 90, but spaced from each other.
- the Air gap surfaces 39 of the north teeth 102 each show axially inward.
- the northern teeth 102 of the second body 31 and the northern teeth 102 of the third body 32 are located not directly opposite each other, but are offset from each other.
- FIG. 33 shows the rotor with the first one Body 40, second body 31 and third body 32.
- the Northern teeth 102 of the second body 31 and the third Body 32 are each arranged so that between adjacent north teeth 102 of the same body, respectively South tooth 41 is provided. Change in the circumferential direction thus each have a north tooth 102, each with a south tooth 41 off.
- the first body 40 is magnetized so that the magnetic flux perpendicular to the air gap surfaces 43 enters the southern teeth 41.
- the northern teeth 102 become like that magnetizes that the magnetic flux lines are perpendicular to the air gap surfaces 39 from the northern teeth 102 escape.
- the arrangement of the bodies 40, 31 and 32 provides for each a north tooth 102 and a south tooth 41 are opposite.
- Figure 35 shows a plan view nested north teeth 102 and south teeth 41.
- FIG. 36 shows the north teeth 102 and Southern teeth 41 with a part of the stator.
- the Stator windings 24 are on a connection plate 103rd attached, emerge from the two ends of the stator windings.
- FIG. 37 shows transformer cores 104, made of soft magnetic material, e.g. Iron, insist. These transformer cores 104 are essentially T-shaped, wherein the horizontal part of the Ts radial and the vertical part of the Ts run axially. There are pro Transformer core 104 each have two recesses 1041 and 1042 provided in which the loops are inserted. The transformer cores 104 are distributed in the circumferential direction around the south core 42 and are in the axial direction Height of the south core 42. The wound hang Transformer cores in the axial air gap of the Axialklauenpols and cover parts of the lateral surface of the rotor.
- These transformer cores 104 are essentially T-shaped, wherein the horizontal part of the Ts radial and the vertical part of the Ts run axially.
- There are pro Transformer core 104 each have two recesses 1041 and 1042 provided in which the loops are inserted.
- the transformer cores 104 are distributed in the circumferential direction around the south core 42 and are in
- FIG. 38 shows the transformer cores 104 along with the stator windings 24, each around the Transformer cores 104 are wound.
- FIG. 39 shows the transformer cores 104 together with the loops 240, connection plates 103 as well a carrier 100, on which the transformer cores 104 be attached so that they are mechanically stable.
- the individual transformers can as be formed standard commercial transformers.
- the standard transformer cores become individual wrapped and then into the carrier 100, inserted.
- the carrier becomes a flat band generated by carrier elements 130, in each of which Transformer is inserted and fixed, for example via a clamping, gluing or Welded joint.
- the tape is guided that the transformers are in the space between Northern teeth 102 and southern teeth 41 are introduced.
- the band is closed with its two ends, so that the polygon is created.
- the carrier is then Statorframepolygon is formed.
- FIG. 40 shows the rotor 11 together with the carrier 100.
- the Northern teeth 102 of the second body 31 As well as the above southern teeth 41 to see.
- Through openings of the Carrier 100 are air gap surfaces 39 and 43 can be seen.
- FIG. 41 shows a plan view as in FIG Figure 40 parts of the rotor and the stator. Here are however, the southern teeth 41 and not the northern teeth shown. In addition, the T-shaped transformer cores 104 shown. It can be seen that the southern teeth 41 at a Rotational movement over the transformer cores 104 swipe without touching them.
- Figure 42 shows the stator 12 and the Rotor 11 in the assembled state.
- FIG. 43 shows the axial flow machine Figure 42 in cross section.
- the cut runs along the Line C-C of Figure 40. It points to the left Southern teeth 41 of the first body while on the right Side through the northern teeth 102 of the third body 32nd is cut.
- the northern teeth 102 of the second body 31 and the right southern teeth 41 of the first body 40 are hidden in this view.
- Between the first body 41 and second body 31 is a first one permanent magnetic disc 110 is provided between the first body 41 and second body 31 .
- the first Permanent magnetic disc 110 is divided into one North pole N and a south pole S.
- the polarization direction in the first permanent magnetic disk 110 is axial.
- the south pole S points to the first body 40 and the North pole N to the second body 31.
- the second permanent magnetic disk 110 is also concentric around the rotation axis 90 is provided and is also in a Split north and south pole.
- the south pole S points in Direction of the first body 40 and the
- the polarization causes the Magnetic field lines starting from the north pole N initially axially extend outwardly, after which they are in the side wall 33rd be deflected radially outwards.
- the field lines occur the air gap surfaces 39 substantially perpendicular to this axially.
- the field lines continue to run axially through the air gaps 281 and 282 and the Transformer cores 104 and enter each of the Air gap surfaces 43 of the first body 40 radially again, after which initially in the radial direction inside and then deflected in the axial direction to the outside finally to the South Pole to meet permanent magnetic disks 110.
- Air gaps 283 and 284 take the form of Circular cylinder walls concentric around the axis of rotation 90 run.
- Figure 44 shows a cross section of a Embodiment of a synchronous machine, in comparison to Figure 41 additionally rotor windings 510 between the first Body 40 and second body 31 and rotor windings 520 between the first body 40 and third body 32 is provided are.
- the excitation sets off the excitement of the permanent magnetic discs and the excitation by the rotor windings 510 and 520 together.
- Figure 45 shows a cross section of a Embodiment of a synchronous machine, in comparison to Figure 43 instead of the permanent magnetic discs 110 rotor windings 510 between the first body 40 and second body 31 and rotor windings 520 between the first Body 40 and third body 31 are provided.
- Figure 46 shows another Embodiment of a claw pole. This one also contains a North System 30 and a South System 40, though together form a single part. In doing so, the Northern teeth 37 and southern teeth 41 into each other. Northern teeth 37 and Southern teeth 41, however, are spaced apart from each other no short circuit between them arises.
- This rotor is in terms of minimization optimized by stray fluxes and stands out in particular through very short magnetic paths. He leads inside the complete over the lateral surface of the annulus discharged flow without excessively saturating the material inside.
- Figure 47 shows a cross section through the claw pole 29 of Figure 46.
- the claw pole 29 points an inner tube section 38 at a first distance r1 to the center M of the claw pole 29.
- the northern teeth 37 and the southern teeth 41 are provided.
- FIG. 48 shows the claw pole 29 from FIG 46 in another oblique view.
- FIG. 49 shows a cross section along the line D-D through the claw pole of Figure 48.
- the Claw pole 29 ' consists of a single piece, whose basic form is a ring. In the middle of the ring extends an opening 290, into which the rotor windings be introduced. Starting from the channel 290 there are more recesses 291, due to their shape for it take care that the northern and the southern teeth are separated are. The recesses 291 extend outwardly to the air gap.
- Figure 50 shows the cross section through the Claw pole 29 'in another view.
- the recess 291 at the upper cut surface points to the left outside, while the recess 291 in the lower sectional area 293 points to the right.
- the upper jaw tooth is it is a north tooth 37, while it is at the bottom shown jaw tooth is a south tooth 41.
- Figure 51 shows another Embodiment of a claw pole 29 'in the Tilt.
- Figure 46 is no continuous inner pipe section 38 as an inner ring provided, but there are two of each other separate parts following North System 30 and South System 40 are divided. It is thus not only in the outer Ring north and south teeth 37 and 41, but also inside Ring 380 alternate separate north teeth 37 and southern teeth 41 from each other.
- Figure 52 shows a section through the Claw pole 29 'along the line E-E of Figure 51.
- the claw pole 29 'from consists of two parts, a North System 30 and a South System 40, which are so interlocked that one another Northern teeth 37 and southern teeth 41 both at the inner ring 380 as well as the outer ring 381 alternate.
- the assembly This claw pole 29 is particularly simple because e.g. in the north system 30, the rotor windings 50 inserted and then the South System 40 placed over it becomes, so that the claw pole 29 'is formed.
- FIG. 53 shows an embodiment of a Vehicle 1004, in the drive 2 for driving the vehicle 1004 is used.
- the vehicle 1004 as a bicycle is formed, has a manual switching device 1001, a prime mover 1005 by a driver and a Second drive 2 by one presented in this application Synchronous motor on.
- the prime mover has two pedals, two cranks and a bottom bracket shaft.
- points the vehicle 1004 has a front drive pinion for driving a chain 1018, wherein the chain 1018 turn over a second pinion drives an impeller 1025 of the two-wheeler.
- a gearshift 1015 in the form of a hub gear is housed in a wheel hub 1024 of the impeller 1025.
- the drive can also be or four-wheeled motor vehicles as sole propulsion be used for the wheels of motor vehicles.
- Electric machine (1) with a Stator (12) and a rotor (11) around a Rotation axis (90) is rotatably arranged, as well at least one air gap (28) between the stator (12) and Rotor (11), wherein the rotor (11)
- first body (40) and the second bodies (31) extend radially so that the first magnetization element (510) in the axial direction (a) between the second body (31) and the first body (40) for magnetizing the second body and the first one Body (40) is arranged
- first body (40) and the third bodies (32) extend radially so that second magnetization element (520) in the axial direction (a) between the third body (32) and the first body (40) for magnetizing the third body (32) and the first body (40) is arranged
- first body (40) at least an air gap surface (43) facing the stator (12) for conducting a magnetic flux of a first Polarization direction through the air gap (28) opposite,
- the second body (31) and the third body (32) each at least one Air gap surface (39), which the stator (12) for conducting a magnetic flux of a second Polarization direction through the air gap (28) opposite,
- a connector (80) for feeding of electrical current through the first rotor windings (510) and the second rotor windings (510) is provided, wherein the rotation axis (90) passes through the connector (80).
- an electrical line that is the first Connecting rotor windings to the second rotor windings, is provided, wherein the electrical line through a Conduit (54) of the first body (40) extends, wherein the axis of rotation (90) passes through the duct (54).
- the air gap surface (39) of the second body (31) and the air gap surface (39) of the third body (32) touch each other.
- the air gap surfaces (39, 43) of the first body (40), the second body (31) and of the third body (32) each in the form of wall segments are formed of circular cylinders, wherein the wall segments each bounded by four lines, with two each these lines are parallel to each other and the others Lines are at right angles to each other.
- Electric motor (1) with a rotor (11) and a stator (12), wherein the rotor (11) Rotor windings (510, 520) and a claw pole (29), the a generated by a magnetizing element (510) Magnetic field receives, wherein the claw pole (29) a Variety of claw pole teeth (37), wherein the Claw pole teeth (37) respectively
- the cross-sectional area (QH) of the Magnetic field claw neck (34) at least half as large as the area (QL) of the air-gap surface (39).
- the rotor (11) comprises
- Electric machine with one Stator (12) and a rotor (11) around a Rotation axis (90) is rotatably arranged and the Rotor windings for generating a magnetic field in the rotor and an air gap (28) between the stator (12) and rotor (11),
- the connector in the spring Element creating an electrical contact between the connector and the resilient element, wherein the connector is centered about the axis of rotation (90).
- Electric machine with one Stator (12) and a rotor (11) around a Rotation axis (90) is rotatably disposed, as well as a first air gap (281) and a second air gap (282) between stator (12) and rotor (11),
- a magnetizable first body 40
- a magnetizable second body 31
- a magnetizable third body 32
- a first Magnetizing element 510
- a second Magnetizing element 520
- first body (40) and the second bodies (31) extend radially so that the first magnetizing element (510, 110) in the axial direction (a) between the second body (31) and the first body (40) for magnetizing the first body (40) with a first polarization direction and the second body (32) is arranged with a second polarization direction,
- the first body (40) and the third one Body (32) extend radially so that the second Magnetizing element (520, 110) in the axial direction (a) between the third body (32) and the first body (40) for magnetizing the first body (40) with the first polarization direction and the third body (32) is arranged with the second polarization direction,
- first body (40) and the second body (31) each at least one Air gap surface (39, 43) for conducting a magnetic Have flow in the axial direction through the first air gap (281),
- first body (40) and the third body (32) each at least one Air gap surface (35) for conducting a magnetic Flow in the axial direction through the second air gap (282),
- the air gap surfaces (39, 43) the first body (40), the second body (31) and the third body (32) in the radial direction outside the first magnetizing element and the second Magnetizing element are arranged.
- stator is a plurality of Transformers (111), each one a transformer core (104) and stator windings (24) contains.
Abstract
Description
Claims (10)
- Fahrzeugantrieb, der folgendes aufweist:- eine Energiequelle (7) zum Bereitstellen elektrischer Energie;- einen von der Energiequelle (7) gespeisten Synchronmotor (1) mit einem Rotor (11) und einem Stator (12) und mindestens einem Luftspalt (28) zwischen Rotor (11) und Stator (12),wobei der Rotor (11) Rotorwicklungen (510) aufweist zum Erzeugen eines Magnetfelds bei elektrischem Strom (IR) durch die Rotorwicklungen (510),und der Stator (12) Statorwicklungen (24) aufweist zum Erzeugen eines Magnetfelds bei elektrischem Strom (IS) durch die Statorwicklungen (24);- eine Ansteuerschaltung (8, 16) zum Verringern, zumindest in einem Drehzahlbereich des Synchronmotors, des Stroms (IR) durch die Rotorwicklungen (510) bei Erhöhung der Drehzahl des Rotors (11);wobei der Rotor (11)- einen magnetisierbaren ersten Körper (40), einen magnetisierbaren zweiten Körper (31), einen magnetisierbaren dritten Körper (32), ein erstes Magnetisierungselement (510) und ein zweites Magnetisierungselement (520), aufweist,- wobei der erste Körper (40) und der zweite Körper (31) sich radial so erstrecken, dass das erste Magnetisierungselement (510) in axialer Richtung (a) zwischen dem zweiten Körper (31) und dem ersten Körper (40) zum Magnetisieren des ersten Körpers (40) und des zweiten Körpers (31) angeordnet ist,- und der erste Körper (40) und der dritte Körper (32) sich radial so erstrecken, dass das zweite Magnetisierungselement (520) in axialer Richtung (a) zwischen dem dritten Körper (32) und dem ersten Körper (40) zum Magnetisieren des ersten Körpers (40) und des dritten Körpers (32) angeordnet ist,und wobei der erste Körper, der zweite Körper und der dritte Körper jeweils Luftspaltoberflächen (43, 39) zum Leiten von magnetischem Fluss durch den Luftspalt (28) zum Stator aufweist.
- Fahrzeugantrieb nach einem der Ansprüche 1 und 2,dadurch gekennzeichnet, dasseinen Konnektor (80) zum Einspeisen von elektrischem Strom durch die erste Rotorwicklungen und die zweite Rotorwicklungen vorgesehen ist, wobei die Rotationsachse (90) durch den Konnektor (80) verläuft.
- Fahrzeugantrieb nach einem der Ansprüche 1 bis 2,dadurch gekennzeichnet, dasseine elektrische Leitung, die die erste Rotorwicklungen mit der zweiten Rotorwicklungen verbindet, vorgesehen ist, wobei die elektrische Leitung durch einen Leitungskanal (54) des ersten Körpers (40) verläuft, wobei die Rotationsachse (90) durch den Leitungskanal (54) verläuft.
- Fahrzeugantrieb nach einem der Ansprüche 1 bis 3,dadurch gekennzeichnet, dassund die Luftspaltoberfläche (39) des zweiten Körpers (31) und die Luftspaltoberfläche (39) des dritten Körpers (32) sich berühren.
- Fahrzeugantrieb nach einem der Ansprüche 1 bis 4, wobei die Luftspaltoberflächen (39, 43) des ersten Körpers (40), des zweiten Körpers (31) und des dritten Körpers (32) jeweils in Form von Wandsegmenten aus Kreiszylindern ausgebildet sind, wobei die Wandsegmente jeweils von vier Linien begrenzt werden, wobei jeweils zwei dieser Linien zueinander parallel sind und die jeweils anderen Linien im rechten Winkel aufeinander stehen.
- Fahrzeugantrieb nach einem der Ansprüche 1 bis 5, wobei das erstes Magnetisierungselement (510) und das zweite Magnetisierungselement (520) eine permanentmagnetische Scheibe (110) aufweisen, wobei der Nordpol (N) und der Südpol (S) der Scheibe (110) in axialer Richtung hintereinander angeordnet sind.
- Fahrzeugantrieb nach einem der Ansprüche 1 bis 6, wobei der erste Körper (40) und der zweite Körper (31) jeweils mindestens eine Luftspaltoberfläche (39, 43) zum Leiten eines magnetischen Flusses in axialer Richtung durch den ersten Luftspalt (281) aufweisen,und wobei der erste Körper (40) und der dritte Körper (32) jeweils mindestens eine Luftspaltoberfläche (35) zum Leiten eines magnetischen Flusses in axialer Richtung durch den zweiten Luftspalt (282) aufweisen,wobei die Luftspaltoberflächen (39,43) des ersten Körpers (40), des zweiten Körpers (31) und des dritten Körpers (32) in radialer Richtung außerhalb des ersten Magnetisierungselements und des zweiten Magnetisierungselements angeordnet sind.
- Fahrzeugantrieb nach Anspruch 7, wobei ein weiterer Luftspalt (283,284) zwischen dem zweiten Körpers und dem Stator vorgesehen ist, wobei der zweite Körper (31) mindestens eine weitere Luftspaltoberfläche (391) zum Leiten eines magnetischen Flusses in radialer Richtung durch den weiteren Luftspalt (283,284) aufweist.
- Fahrzeugantrieb nach einem der Ansprüche 7 und 8, wobei der Stator eine Vielzahl von Transformatoren (111), die jeweils einen Transformatorkern (104) und Statorwicklungen (24) enthalten, aufweist.
- Fahrzeugantrieb nach Anspruch 9, wobei der Stator (12) einen Rahmen (100) aufweist, an den die Transformatoren (111) befestigt sind.
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DE102007040750A1 (de) | 2007-08-28 | 2009-03-05 | Brusa Elektronik Ag | Stromerregter Synchronmotor insbesondere für Fahrzeugantriebe |
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US5130595A (en) * | 1987-11-23 | 1992-07-14 | Chrysler Corporation | Multiple magnetic paths machine |
US4882515A (en) * | 1988-06-03 | 1989-11-21 | General Motors Corporation | Alternating current generator |
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DE102007040750A1 (de) | 2007-08-28 | 2009-03-05 | Brusa Elektronik Ag | Stromerregter Synchronmotor insbesondere für Fahrzeugantriebe |
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