CN2845305Y - Electromagnetic coupling stepless speed gear - Google Patents
Electromagnetic coupling stepless speed gear Download PDFInfo
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- CN2845305Y CN2845305Y CNU2005200551886U CN200520055188U CN2845305Y CN 2845305 Y CN2845305 Y CN 2845305Y CN U2005200551886 U CNU2005200551886 U CN U2005200551886U CN 200520055188 U CN200520055188 U CN 200520055188U CN 2845305 Y CN2845305 Y CN 2845305Y
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Abstract
The utility model relates to an electromagnetic coupling stepless speed gear, particularly the stepless gear of a vehicle, etc. A current collector and a stator of the stepless speed gear are respectively connected with an AC-DC converter and an DC-AC frequency conversion converter in a power electronic controller. An input shaft or an output shaft is connected with a rotor through the current collector, and the rotor is positioned at the inner cavity of a cyathiform rotor, and is matched with the cyathiform rotor. One end of the cyathiform rotor is connected with the output shaft or the input shaft, and the stator is fixed on a machine base, and is matched with the cyathiform rotor. Cascade connection type electric transmission is integrally combined with electromagnetic slip coupled type mechanical transmission by the stepless speed gear. Non-contact rotary electricity transmission is added, power dividing sink flow is formed, and a speed governing means of the combination of frequency conversion and regulating magnetism is matched. When the range of the stepless gear is kept as wide as the conventional electric transmission, the general transmission efficiency is raised, the regulation performance is good, and the operation is reliable. The components, such as a clutch, an engine starter, etc. can also be omitted, and the utility model can also be directly used as a multi-energy power assembly.
Description
Technical field
The utility model relates to a kind of buncher, specifically is a kind of electromagnetic coupled buncher.This system applies is in adopting in the electromechanical integration equipment of speed change transmission for the conventional truck of single prime mover, oil-electricity mixed power electric automobile and other with Thermal Motor etc.
Background technology
Various apparatuss of transport such as automobile and many other Mechatronic Systems all need to dispose power transmission---the speed changer of scalable running speed, matched load.That adopts at present extensively mostly is manual or automatic step type mechanical transmission based on gear pair, though himself transmission efficiency is higher, but the speed governing quality is good inadequately, and can only on some points of system works scope, guarantee the correct coupling of prime mover and load, cause that overall system efficient descends to some extent on most working points.
Existing buncher mainly contains multi-form bunchers such as various, hydraulic pressure/hydraulic power moving based on mechanical friction transmission, fax.Existing infinitely variable speeds fax is moving mainly to be the moving buncher of tandem type fax.This buncher is seen Fig. 1, comprises power shaft 1, power electronic controller 5, motor 6, motor 7, output shaft 2, for mixed power electric car, also comprises electric energy buffer memory (battery pack) subsystem 9.Two motors 6,7 can be permagnetic synchronous motors, also can be the motors of his type; The power electronic controller comprises AC-DC converter 51 and DC-AC variable frequency inverter 52, and the stator 62 of stator 72, the latter and the motor 6 of the former and motor 7 is electrically connected, and both cooperatively interact and control two rotating speed of motor-torque working point.For the moving buncher of tandem type fax, the mechanical output of prime mover 11 inputs must all be converted to electrical power earlier, and then be converted to mechanical output output, whole power circuit will experience the machine-electricity of motor 7, the electricity of motor 6-machine conversion and in a plurality of conversion links such as the AC-DC of power electronic controller and DC-ACs, cause its efficient on the low side.In fact, general significantly low than step type mechanical transmission of the transmission efficiency of existing various bunchers.
The oil-electricity mixed power electric automobile has the considerable energy saving environment protecting, is one of developing direction of automotive engineering, but it need set up subsystems such as motor (generating/electronic), battery pack and power flow concentration than conventional automobile.Prior art also fails to realize multiple functions such as generating, electronic, engine start, clutch, speed change, power flow concentration are rolled into one, and it is higher with speed change system equipment complexity, manufacturing cost to conflux with actuation force.
The utility model content
The purpose of this utility model is to overcome the shortcoming of prior art, provides a kind of and realize automatic stepless speed variator efficiently in than the large speed ratio scope, engine is remained in the optimum working zone turn round under the varying load condition.Another purpose of the present utility model is to replace electric system in engine primer, clutch, gear-shift mechanism or the mixed power electric car in the orthodox car, power flow concentration device etc.Provide a kind of conventional truck, oil-electricity mixed power electric automobile and other of being adapted to adopt the power flow concentration used in the electromechanical integration equipment of speed change transmission and the system of infinitely variable speeds one thus, and this system possess the characteristic that compact conformation, efficient height, I/O axle can independently be regulated and control.
For achieving the above object, the utility model adopts following technical scheme:
On the basis of the tandem mechanical-electric coupling scheme of or mixed power electric car moving, adopt on the basis of permagnetic synchronous motor scheme especially therein in the existing stepless fax of tandem type, implement structural modification, electromagnetism slippage coupling (clutch) device of mechanical energy and certain assembly of motor can be directly transmitted in formation, and set up devices such as additional adjustable magnetic coil, contactless mutual inductance current collector, constitute a kind of electromagnetic coupled buncher that possesses the power split function.
The moving scheme efficient of the existing tandem type infinitely variable speeds fax of typical case as shown in Figure 1 is on the low side, if but such scheme is changed by shown in Figure 2, situation will greatly be taken on a new look.This change mainly comprises:
The first, the electrical power output of motor 7 is changed on the rotor 71 from stator 72, and set up a current collector 8 and draw through lead.Just following follow-up change is for convenience done in motor 7 equivalence fully before and after changing like this.Certainly, for permanent-magnet synchronous type motor winding unshakable in one's determination and permanent magnet are exchanged, promptly 72 is that magneto, 71 is winding type unshakable in one's determination; In addition, be to improve functional reliability, current collector 8 is preferably contactless, as a kind of mutual inductance type noncontact current collector of hereinafter describing etc.
The second, remove the constraint of " stator " 72 of motor 7, and make it to fix up with the rotor 61 and the axle 2 of motor 6 around its axial line rotational freedom.
Scheme is that the electromagnetic coupled buncher comprises power shaft, output shaft, support, power electronic controller, current collector, rotor, stator and magneto or Wound-rotor type or squirrel-cage cup-shaped rotor, be supported on support, current collector, rotor, stator and magneto or Wound-rotor type or squirrel-cage cup-shaped rotor power shaft and output shaft coaxial line; Described current collector and stator respectively with the power electronic controller in the AC-DC converter be connected with the DC-AC variable frequency inverter; Power shaft or output shaft are connected with rotor by current collector, and rotor is positioned at the cup-shaped rotor inner chamber, cooperate with cup-shaped rotor, and the cup-shaped rotor other end is connected with output shaft or power shaft, and stator is fixed on the support, cooperates with cup-shaped rotor.Described current collector is for to cooperate mutual inductance type noncontact current collector or the electric brush slip ring formula current collector that constitutes by the inductive primary coil with secondary coil, the described non-mutual inductance type that connects touches current collector inductive primary coil and is arranged on the power shaft, its coil windings is circumferential or axial, and be connected with the coil windings lead that is arranged on the rotor on the power shaft jointly, the inductive secondary winding is identical with the inductive primary coil, and cooperates with the inductive primary coil.Described power electronic controller also can be provided with three transducers, cooperates with output shaft, power shaft and prime mover respectively, and links to each other with the power electronic controller by lead.
Adopt the principle of technique scheme as follows:
As shown in Figure 4, when the rotor 71 of prime mover 11 drive motors 7 generates electricity with respect to " stator " 72 rotations, interactional between the two electromagnetic torque will drag " stator " 72 and affixed with it rotor 61 and output shaft 2, do in the same way but rotatablely moving of can not waiting of speed with rotor 71.Referring to the model of Fig. 4, this is equivalent to become the hold concurrently assembly of electromagnetism slippage coupling (clutch) device of a motor to 7, the part mechanical output of prime mover 11 directly is transferred to load 10 through output shaft 2, and motor 7 is with relative rotation speed (speed discrepancy) Δ ω=ω
1-ω
2As its " synchronous generator rotating speed ", the remainder of original machine power is converted to electrical power, transmit and convert to once more mechanical output via the moving motor 7--along separate routes of fax power electronic controller 5--motor 6 and converge to axle 2, finally also be transferred to load 10.Become motor 7 of the electromagnetic slip coupling assembly of holding concurrently, the efficient of its transmitted power both had been higher than single electromagnetic slip coupling, also was higher than single motor.For the former, be because it will become single electromagnetic slip coupling the electric power that has of the moving shunt of fax originally as the power that the current vortex heating loss falls, for the latter, be because it only allows the part of gross power transmit along separate routes via efficient fax on the low side relatively is moving, so overall efficiency is improved.Following fundamental formular of setting up according to Fig. 4 and the concise and to the point theory analysis of being done provide further confirmation to this.
If ω represents angular speed, T represents torque, and P represents power (stream), and the subscript e of symbol represents that fax is along separate routes moving.Power from prime mover is P
1=T
1ω
1That part of mechanical output P that directly transmit through electromagnetic slip coupling 18 this moment
HCan think that efficient is about 1.0, i.e. P
H=T
1ω
2All the other can be P for 7 power that convert electric energy to
e=T
1Δ ω=T
1(ω
1-ω
2), and P is arranged
1=P
e+ P
HFax efficiency of movement η
e<1.0, P
eThrough the moving loss to some extent along separate routes of fax, be delivered to the η that is in the load
eP
eThe effective power that drives load is P
2=T
2ω
2T wherein
2=T
1+ T
E2, and T
E2=η
eP
e/ ω
2Utilize these fundamental formulars easily to know by inference: at ω
2≤ ω
1The deceleration transmission section, speed change transmission gross efficiency η=P
2/ P
1=η
e+ (1-η
e) ω
2/ ω
1, perseverance has η>η
e, the moving height of the conventional tandem type fax of constant proportion Fig. 1, and with ω
2Increase is the gesture that further increases, and works as ω
2→ ω
1The time η → 1.0.In like manner as can be known, at ω
2〉=ω
1The overdrive section, η is with ω
2Increase descends gradually from 1.0, but still keeps higher level in usage range, and because of prime mover (engine) is operated in the fuel-efficient efficient district of high speed light loading this moment, also the decline of transmission efficiency is provided to remedy.
Adopt the beneficial effect that has produced after the above-mentioned change technical scheme to comprise:
The first, when suitable broader range of infinitely variable speeds was moved in maintenance and conventional fax, overall efficiency was improved, thereby produced energy-saving effect.
The second, can save clutch and engine primer; For mixed power electric car, merge speed changer and motor two big discrete parts and held a concurrent post the power flow concentration device, going back nature provides advanced connection in series-parallel (series-parallel connection) to drive function and braking energy recovery function; For other application scenarios, the moving rated power capacity of each components and parts along separate routes of fax can obviously reduce; These all can bring simplified system, reduce cost, improve the effect of performance.
More than set forth basic functional principle of the present utility model, adopted Fig. 2, Fig. 3 and Fig. 4 of being convenient to understand, still remain with inconvenience uses obvious tandem type topological layout for convenient.According to different instructions for uses and characteristics, specific embodiments of the present utility model can be numerous can letter, form multiple derivative schemes., as embodiment the utility model is described in further details below in conjunction with a basic model scheme that takes into account factors such as compactedness, modulating properties and some derivative schemes.
Description of drawings
Fig. 1 is the moving scheme schematic diagram of existing tandem type infinitely variable speeds fax, and when this scheme was used for series hybrid power electric vehicle, electric energy buffer memory (battery pack) subsystem of representing with double dot dash line among the figure 9 was for indispensable.Other parts are respectively among the figure: power shaft 1, output shaft 2, motor 7 (comprise its rotor 71 and stator 72, use mainly as generator), motor 6 (comprises its stator 62 and rotor 72, use mainly as motor), power electronic controller 5, power electronic controller 5 (comprise parts such as AC-DC transducer 51 and DC-AC variable frequency inverter 52, be used for controlling above-mentioned two rotating speed of motor-torque working point), prime mover 11 (as hot machines such as internal combustion engines), load 10 (as automobile drive axle) etc.; Both do not belong to described variable ratio drive system because of the back, so dot.Motor 7,6 can be the motor of permagnetic synchronous motor or other types among the figure.
Fig. 2 is the utility model execution mode 2 basic functional principle schematic diagrames, current collector shown in the figure 8, the same Fig. 1 of all the other component part numbers meanings.
Fig. 3 and Fig. 4 are respectively the simplified model of the moving and electromagnetic coupled infinitely variable speeds transmission of the existing stepless fax of tandem type, electromagnetism slippage coupling (clutch) device 18 among the figure, the same Fig. 2 of all the other each component part numbers meanings.The symbol that also has non-vanishing unit number among the figure, wherein ω and circular arc arrow are represented angular speed, and T and circular arc arrow are represented torque, and P and thick-line arrow are represented power (stream), and the subscript e of symbol refers to that fax is moving along separate routes, other subscripts refer to corresponding component part numbers.
Fig. 5 is the structural representation of the utility model execution mode 1.Support shown in the figure 3, additional adjustable magnetic coil 4, cup-shaped rotor 67, inductive primary coil 81, inductive secondary 82, speed probe 13,12, (engine) throttle sensing 14 devices, the same Fig. 2 of all the other component part numbers meanings.
Fig. 6 is the utility model execution mode 1 cup-shaped rotor field structure unfolded surface schematic diagram, shown in the figure: the N-permanent magnet arctic, the S-permanent magnet South Pole, Fe-magnetic pole iron.
Fig. 7 is the scheme schematic diagram of the utility model execution mode 7.Shown in the figure: induction machine rotor 73, the same Fig. 2 of all the other component part numbers meanings.
Embodiment
Below in conjunction with accompanying drawing embodiment of the present utility model is described in further detail, but execution mode of the present utility model is not limited thereto.
As shown in Figure 5, form mutual support relation by bearing between power shaft 1, output shaft 2 and the support 3.Rotor 71 is fixed on the power shaft 1, air gap is arranged places the inner chamber of cup-shaped rotor 67 together with its axial coil windings, and cup-shaped rotor 67 is affixed with output shaft 2.Stator 62 is fixed on the support 3, has air gap ground to cooperate with cup-shaped rotor 67 outer surfaces.Additional adjustable magnetic coil 4 links to each other with power electronic controller 5 by lead for circumferentially being wrapped in the dc coil in stator 62 cannelures unshakable in one's determination.Additional adjustable magnetic coil 4 senses of current decision increases the still weak magnetic action of magnetic to 67 of the cup-shaped rotors of permanent magnetism, and the size of electric current determines the size of this adjustable magnetic effect.Inductive primary coil 81 has constituted the non-contacting current collector 8 of mutual inductance type with inductive secondary 82, and wherein inductive primary coil 81 links to each other by lead with winding on the rotor 71, and inductive secondary 82 is fixed on the support 3.Inductive primary coil 81 is an iron core with power shaft 1 all with the coil windings of inductive secondary 82, and along circumferentially coiling, the similar transformer of its operation principle is not even power shaft 1 produces the generating or the electromotive action of similar lead cutting magnetic line between the two yet when rotating.Correspondingly, cup-shaped rotor 67 has the field structure that is similar to composite excitation brushless direct-current machine, and its unfolded surface is made up of permanent magnet pole N, S and magnetic pole iron Fe two parts as shown in Figure 5, and the latter provides low reluctance magnetic circuit for magnetic flux.Power electronic controller 5 is made up of AC-DC converter 51, DC-AC variable frequency inverter 52 and dc bus and control computer etc., is used for controlling the rotary speed-torque working point of described two mixed excitation electric machines; The winding of it and stator 62 self, additional adjustable magnetic coil 4 and inductive secondary 82, transducer 12,13,14 etc. link to each other with lead, also be provided with energy-storage battery+/-Interface Terminal, to satisfy the needs of application such as mixed power electric car.Transducer 12,13 is gathered the tach signal of output shaft 2, power shaft 1 respectively, and transducer 14 is gathered the accelerator open degree signal of prime mover (engine), and these signals are all presented to power electronic controller 5.
During use, when from power shaft 1 input prime mover power, circumferentially inductive primary coil 81 that twines and rotor 71 all rotate with power shaft 1, and can establish rotating speed is ω
1Axial winding on the rotor 71 cuts its magnetic field on every side with the relative rotation speed Δ ω with permanent magnetism cup-shaped rotor 67 and produces alternating current, equivalence has constituted a synchronous machine, its electric current is fed to inductive primary coil 81 through lead, and sense on the inductive secondary 82, deliver to power electronic controller 5 through lead again.In generating, the electromagnetic torque of rotor 71 and cup-shaped rotor 67 interphase interactions of permanent magnetism will drag cup-shaped rotor 67 and output shaft 2 with rotational speed omega
2=ω
1-Δ ω rotation directly is transferred in the load 10 that is connected on output shaft 2 downstreams with the mode that the is equivalent to electromagnetic slip coupling part mechanical output with prime mover 11.Meanwhile, prime mover that signal reflected and load operation situation (rotating speed, torque, accelerator open degree etc.) that power electronic controller 5 is gathered according to transducer 12,13,14, by the control strategy of having stored, from the electric current of rotor 71 after modulating with different sizes and forms (three-phase alternating current of given frequency, single-phase DC), present respectively to axial stator 62 windings and circumferential additional magnet exciting coil 4.Wherein three-phase alternating current accounts for the overwhelming majority of power electronic controller 5 electromotive power outputs, changes into another part mechanical output that acts on the output shaft 2 via stator 62 and the synchronous machine that cup-shaped rotor 67 equivalences constitute, with rotational speed omega
2Be transferred to load, the frequency of three-phase alternating current is given also therefore will be with ω
2Variation adjust in real time.And the single-phase DC electricity that puts on adjustable magnetic coil 4 only accounts for the very fraction of power electronic controller 5 electromotive power outputs relatively, its formed adjustable magnetic flux mainly constitutes path via the magnetic pole iron of iron core, air gap and the cup-shaped rotor 67 of support 3, stator 62, and with cup-shaped rotor 67 on the metastable magnetic flux that forms by permanent magnet pole synthesize total magnetic flux.Change the size and the polarity of exciting current, with regard to the magnetic field intensity around the scalable cup-shaped rotor 67, thus the rotational speed omega of regulating power shaft 1, output shaft 2
1, ω
2And rotation speed difference deltan ω.If there is not adjustable magnetic coil 4,, can directly actuatedly only be load speed ω at this moment though also can come speed governing by three-phase alternating current frequency modulation to 5 outputs of power electronic controller
2, and ω
1And Δ ω is with load behavior [T
2, ω
2] variation can't directly control.Equipment such as vehicle is for purposes such as energy-conservation and raising dynamic property, and rotational speed omega can be directly controlled in requirement
1, so that make engine under given throttle, can be stabilized in the ideal operation point [T of requirement
1, ω
1], allow rotational speed omega
2(and speed of a motor vehicle) adapts to load behavior and changes.Set up the magnetism-regulating type speed governing and make the suitable control strategy (software) of controller K configuration, this control characteristic is achieved, can also work in coordination with frequency-adjustable speed-adjustable and satisfy ω
2And Δ ω changes the requirement that can control with load behavior.
For the reverse gear setting of drive systems such as vehicle, can change the phase sequence of output three-phase alternating current by power electronic controller 5, the equivalent synchronous motor is reversed realize.The another one method is to get final product to increasing a simple armstrong's patent formula commutator between the load 10 at prime mover 11.This method transmission efficiency is higher, can also do long reverse gear operation.
Compare with principle assumption diagram shown in Figure 4 with schematic diagram shown in Figure 2, embodiment 1 as the utility model basic model has obtained following key improvements: first, originally obvious two large divisions's tandem type topological structure, the cramped construction of improvement becomes double-rotor machine monomer, similar is convenient to mounting arrangements and weight reduction.The second, by adopting the special field structure of additional adjustable magnetic coil and cup-shaped rotor, original magneto has all been become mixed excitation electric machine, the effective way of regulating prime mover and load speed or working point simultaneously is provided, improved modulating properties.The 3rd, a kind of contactless current collector based on the sensor transformer principle is provided, when improving system's operational reliability, do not produce generating resistance as prime mover additional load, help raising the efficiency.
With prime mover among the embodiment 1 11 be connected with output shaft 2, load 10 is connected with power shaft 1, other structure is fully with embodiment 1.In the present embodiment, just the transfer input shaft among the embodiment 1 changes output shaft into, and output shaft converts power shaft to, and the effect that obtains like this is identical with embodiment 1.
Adopt the contactless current collector that constitutes by inductive primary coil 81 and inductive secondary 82 in the conventional contact electric brush slip ring current collector alternate embodiment 1.Can reduce cost, weight and system complex degree like this, but system reliability descends to some extent.
Embodiment 4
Make the inductive primary coil 81 of embodiment 1 and the circumferential canoe of inductive secondary 82 into axial canoe, can be according to the work of AC induction motor principle, inductive primary coil 81 is an armature, inductive secondary 82 is a stator.The other parts structure is with embodiment 1.This structure is compacter under certain condition, but the generating resistance can increase additional load to prime mover.
Additional adjustable magnetic coil 4 among the cancellation embodiment 1, the other parts structure is with embodiment 2.The field structure of the structure of stator 62, cup-shaped rotor 67 and power electronic controller 5 all can be simplified like this, thereby reduce cost, but governor control characteristics can variation.
Employing is similar to the principle and the technology of brushless synchronous machine band rotary rectifier diode and self-excitation winding, make the self power generation of cup-shaped rotor winding, self-rectifying, self-excitation, cup-shaped rotor among the embodiment 2 67 is transformed into non-permanent magnet rotor, and the other parts structure is with embodiment 2.Avoided the fault of permanent magnet possibility loss of excitation like this, and exempted from, but the complexity of system increases, decrease in efficiency with the more expensive permanent magnet of price.
As shown in Figure 7, with prime mover 11 and load 10 exchanges, power shaft 1 is affixed with cup shell rotor 67 on embodiment 2 bases, and rotor 71 originally and inductive primary coil 81 are replaced by an induction machine rotor 73 with mouse cage or winding.Inductive secondary 82 originally is transformed into axial winding, becomes stator winding unshakable in one's determination.Like this, the cup shell rotor 67 of magneto, rotor 73 and coil 82 have just constituted the doubly-fed adjustable speed alternating current impression asynchronous machine of two stators equivalently, and its special character is that main " stator " rotating magnetic field is provided by cup shell rotor 67.This outer cup rotor 67, stator 62 and additional adjustable magnetic coil 4 have constituted a hybrid exciting synchronous motor again equivalently.No longer included obvious " electromagnetic slip coupling " effect in the present embodiment, but existence because of the coil 82 that becomes stator winding unshakable in one's determination, the doubly-fed adjustable speed of output shaft 2 is achieved, winding induced current on the rotor 73 can be fed down on the stator 62 be used, thereby raise the efficiency.To the regulation and control of power shaft 1 rotating speed, be similar to embodiment 2, mainly realize by adjustable magnetic.
Embodiment 8
As shown in Figure 4, mainly form by power shaft 1, output shaft 2, motor 7, current collector 8 and power electronic controller 5.Motor 7 is cooperated with rotor 72 by stator 71 and constitutes, and motor 6 is cooperated with rotor 62 by stator 62 and constitutes.The rotor 71 of motor 7 is fixed on the power shaft 1, and its stator 72 is connected with output shaft 2, and the rotor 61 of motor 6 is fixed on the output shaft 2, and its stator is fixed on the support 3.Motor 6 and motor 7 constitute the tandem type topological structure with obvious two large divisions.Current collector 8 is an electric brush slip ring formula current collector.Power electronic controller 5 comprises AC-DC converter 51 and DC-AC variable frequency inverter 52, and AC-DC converter 51 joins by the rotor 71 of current collector 8 with motor 7; The stator 62 of DC-AC variable frequency inverter 52 and motor 6 joins.Prime mover 11 is an internal combustion engine, provides motive power by power shaft 1 for system.Load is that automobile (drive axle) connects output shaft.Electric energy buffer memory (battery pack) subsystem is connected with power electronic controller 5 by lead.The shortcoming of this execution mode mainly is that structure is compact inadequately, and governor control characteristics is also slightly poor.
With the synchronous machine among embodiment 1-6 and the embodiment 86,7 both or one of change in three-phase alternating current, single phase alternating current (A.C.), direct current or the switched reluctance machines any into, current collector 8 also can change into contactless.Other structure is with embodiment 8.
In the utility model, one or two equivalent synchronous motor in the foregoing description scheme is transformed into the motor of other types, or " falling to use " and the combination thereof of the various embodiments described above scheme, all can form other embodiment of the present utility model.
Claims (8)
1, electromagnetic coupled buncher, comprise power shaft (1), output shaft (2), support (3), power electronic controller (5), be supported on support (3), it is characterized in that: described system also comprises current collector (8), rotor (71), stator (62) and magneto or Wound-rotor type or squirrel-cage or laminate core type cup-shaped rotor (67) power shaft (1) and output shaft (2) coaxial line; Described current collector (8) and stator (62) respectively with power electronic controller (5) in AC-DC converter (51) be connected with DC-AC variable frequency inverter (52); Power shaft (1) or output shaft (2) are connected with rotor (71) by current collector (8), rotor (71) is positioned at cup-shaped rotor (67) inner chamber, cooperate with cup-shaped rotor (67), cup-shaped rotor (67) one ends are connected with output shaft (2) or power shaft (1), stator (62) is fixed on the support (3), cooperates with cup-shaped rotor (67).
2, electromagnetic coupled buncher according to claim 1, it is characterized in that: described electromagnetic coupled system also comprises additional adjustable magnetic coil (4), described additional adjustable magnetic coil (4) links to each other with power electronic controller (5) by lead for circumferentially being wrapped in the cannelure on stator (62) iron core.
3, electromagnetic coupled buncher according to claim 2 is characterized in that: described current collector (8) is for being cooperated mutual inductance type noncontact current collector or the electric brush slip ring formula current collector that constitutes with inductive secondary (82) by inductive primary coil (81); The described non-mutual inductance type that connects touches current collector inductive primary coil (81) and is arranged on the power shaft (1), its coil windings is circumferential or axial, and be connected with the coil windings lead of rotor (71) on being arranged on power shaft (1) jointly, inductive secondary (82) is fixed on the support (3), and its winding is identical with inductive primary coil (81).
4, electromagnetic coupled buncher according to claim 3 is characterized in that: described cup-shaped rotor (67) is to comprise rotary rectifier pipe and the self power generation of self-excitation winding or the wound rotor induction machine rotor of self-rectifying or self-excitation.
5, according to any described electromagnetic coupled buncher of claim 1 to 4, it is characterized in that: described power electronic controller (5) also comprises transducer (12,13,14), described transducer (12,13,14) cooperates with output shaft (2), power shaft (1) and prime mover (11) respectively, and links to each other with power electronic controller (5) by lead.
6, according to any described electromagnetic coupled buncher of claim 1 to 4, it is characterized in that: described power electronic controller (5) is gone up the power interface (53,54) that is provided with, and negative pole and the positive pole with battery pack subsystem (9) joins respectively.
7, the electromagnetic coupled buncher, comprise power shaft (1), output shaft (2), support (3), power electronic controller (5), be supported on support (3) power shaft (1) and output shaft (2) coaxial line, it is characterized in that: described system also comprises current collector (8), motor (7) and motor (6), described motor (7) comprises stator (71) and rotor (72), described motor (6) comprises stator (62) and rotor (61), described rotor (71) is fixed on the power shaft (1), stator (72) is connected with output shaft (2), described rotor (61) is fixed on the output shaft (2), and stator (62) is fixed on the support; Described current collector (8) and stator (62) respectively with power electronic controller (5) in AC-DC converter (51) be connected with DC-AC variable frequency inverter (52).
8, electromagnetic coupled buncher, comprise power shaft (1), output shaft (2), support (3), power electronic controller (5), be supported on support (3), it is characterized in that: described system also comprises cup shell rotor (67), rotor (73), inductive secondary (82) power shaft (1) and output shaft (2) coaxial line; Described power shaft (1) is affixed with cup shell rotor (67), described inductive secondary (82) is positioned at output shaft (2) end, be fixed on the base (3), described rotor (73) is connected with output shaft (2), air gap is arranged passes inductive secondary (82), extends in cup-shaped rotor (67) opening, its coil axes is to winding, cooperate with cup-shaped rotor (67) with inductive secondary (82) respectively, stator (62) is fixed on the support, cooperates with cup-shaped rotor (67); Additional adjustable magnetic coil (4) links to each other with power electronic controller (5) by lead for circumferentially being wrapped in the cannelure on stator (62) iron core.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CNU2005200551886U CN2845305Y (en) | 2005-03-03 | 2005-03-03 | Electromagnetic coupling stepless speed gear |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CNU2005200551886U CN2845305Y (en) | 2005-03-03 | 2005-03-03 | Electromagnetic coupling stepless speed gear |
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| CN2845305Y true CN2845305Y (en) | 2006-12-06 |
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| CN100386956C (en) * | 2005-03-03 | 2008-05-07 | 广州汽车工业集团有限公司 | Electromagnetic coupling variable-speed drive system |
| CN101951117A (en) * | 2010-05-04 | 2011-01-19 | 王培森 | Automobile automatic continuously variable transmission |
| CN101388586B (en) * | 2008-09-27 | 2011-10-05 | 中国科学院电工研究所 | Electric power stepless speed changer integrated with double speed ratio output mechanism |
| CN102651597A (en) * | 2011-02-24 | 2012-08-29 | 株式会社东芝 | Permanent-magnet type electric rotating machine |
| CN101222172B (en) * | 2006-12-22 | 2013-03-27 | 通用电气公司 | Variable magnetic coupling of rotating machinery |
| CN103155385A (en) * | 2010-08-05 | 2013-06-12 | 马丁·雅各布斯·赫爱耶马凯斯 | Rotating electromechanical converter |
| CN103352753A (en) * | 2013-07-02 | 2013-10-16 | 龙口中宇热管理系统科技有限公司 | Heat removing device, electromagnetic fan clutch, control method of electromagnetic fan clutch and stepless speed regulating system |
| CN104393687A (en) * | 2009-02-26 | 2015-03-04 | 英属哥伦比亚大学 | Receiver and power transfer apparatus |
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| CN108964410A (en) * | 2017-05-27 | 2018-12-07 | 熵零技术逻辑工程院集团股份有限公司 | A kind of transmission device |
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2005
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| CN100386956C (en) * | 2005-03-03 | 2008-05-07 | 广州汽车工业集团有限公司 | Electromagnetic coupling variable-speed drive system |
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| CN104393687A (en) * | 2009-02-26 | 2015-03-04 | 英属哥伦比亚大学 | Receiver and power transfer apparatus |
| CN104393687B (en) * | 2009-02-26 | 2017-08-11 | 英属哥伦比亚大学 | Receiver and power transmitting device |
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| CN103155385B (en) * | 2010-08-05 | 2016-08-17 | 荷兰应用科学研究会(Tno) | Rotary electric mechanical converter |
| CN103155385A (en) * | 2010-08-05 | 2013-06-12 | 马丁·雅各布斯·赫爱耶马凯斯 | Rotating electromechanical converter |
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| CN103352753B (en) * | 2013-07-02 | 2016-04-20 | 龙口中宇热管理系统科技有限公司 | Electromagnetic fan clutch and controlling method and continuous speed regulation system |
| CN103352753A (en) * | 2013-07-02 | 2013-10-16 | 龙口中宇热管理系统科技有限公司 | Heat removing device, electromagnetic fan clutch, control method of electromagnetic fan clutch and stepless speed regulating system |
| CN105006951A (en) * | 2015-08-06 | 2015-10-28 | 江苏磁谷科技股份有限公司 | Magnetic coupling transmission device running at constant power and adjustable speed |
| CN106961207A (en) * | 2016-01-12 | 2017-07-18 | 亓英军 | Electromagnetic speed variator |
| CN108964411A (en) * | 2017-05-27 | 2018-12-07 | 熵零技术逻辑工程院集团股份有限公司 | A kind of transmission device |
| CN108964410A (en) * | 2017-05-27 | 2018-12-07 | 熵零技术逻辑工程院集团股份有限公司 | A kind of transmission device |
| CN108964387A (en) * | 2018-06-06 | 2018-12-07 | 东南大学 | The double-deck standard squirrel cage conductor rotor high torque density permanent-magnet speed governor |
| CN108964387B (en) * | 2018-06-06 | 2019-10-11 | 东南大学 | The double-deck standard squirrel cage conductor rotor high torque density permanent-magnet speed governor |
| CN109412386A (en) * | 2018-12-17 | 2019-03-01 | 大连交通大学 | A kind of phase-wound rotor permanent magnet speed regulation device |
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