CN1310420C - Control device of elevator - Google Patents
Control device of elevator Download PDFInfo
- Publication number
- CN1310420C CN1310420C CNB038010275A CN03801027A CN1310420C CN 1310420 C CN1310420 C CN 1310420C CN B038010275 A CNB038010275 A CN B038010275A CN 03801027 A CN03801027 A CN 03801027A CN 1310420 C CN1310420 C CN 1310420C
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- current
- magnetic pole
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B1/00—Control systems of elevators in general
- B66B1/02—Control systems without regulation, i.e. without retroactive action
- B66B1/06—Control systems without regulation, i.e. without retroactive action electric
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B1/00—Control systems of elevators in general
- B66B1/24—Control systems with regulation, i.e. with retroactive action, for influencing travelling speed, acceleration, or deceleration
- B66B1/28—Control systems with regulation, i.e. with retroactive action, for influencing travelling speed, acceleration, or deceleration electrical
- B66B1/30—Control systems with regulation, i.e. with retroactive action, for influencing travelling speed, acceleration, or deceleration electrical effective on driving gear, e.g. acting on power electronics, on inverter or rectifier controlled motor
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/12—Stator flux based control involving the use of rotor position or rotor speed sensors
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- Engineering & Computer Science (AREA)
- Automation & Control Theory (AREA)
- Power Engineering (AREA)
- Control Of Ac Motors In General (AREA)
- Elevator Control (AREA)
- Indicating And Signalling Devices For Elevators (AREA)
- Control Of Motors That Do Not Use Commutators (AREA)
- Control Of Multiple Motors (AREA)
Abstract
The construction of the present invention is that individual current control units are provided to respective motor winding systems of a multi-winding motor that constitutes a hoisting machine (6) for lifting/lowering a cage (8) to give the same torque instruction, and thetaa and thetab obtained by respectively adding magnetic pole adjustment elements (thetaadja, thetaadjb) to an output (theta) from a rotation detector (10) are given to a 3-phase/2-phase converter and a 2-phase/3-phase converter to thereby control a q-axis current uniformly and control a magnetic flux in each system to be equal, whereby it is possible to improve a current imbalance between motor winding systems.
Description
Technical field
The present invention relates to a kind of elevator control gear, particularly relate to the big capacity elevator control device that a plurality of inverters of connection and convertor assembly drive the hoist engine that is made of multi-winding motor.
Background technology
The drive unit that the double-deck elevator of car and following car is gone up in jumbo very high speediness elevator or connection is carried out the control of motor by a plurality of inverters and convertor assembly.
In recent years, the high stratification of building is developed, is that the very high speediness elevator of purpose and the double-deck elevator that once can carry the passenger of 2 amounts obtain utilizing with a large amount of conveyings of passenger.The motor that drives such elevator uses multi-winding motor capacious.
The control device that carries out its control is for connecting the formation that many inverters and convertor assembly carry out the control of motor.For example, Fig. 1 illustrates existing system example.
As shown in the drawing, connect current transformer 102a and current transformer 102b side by side at power supply 101.Connect inverter 103a at current transformer 102a, between current transformer 102a and inverter 103a, be connected capacitor 104a.Connect inverter 103b at current transformer 102b, between current transformer 102b and inverter 103b, be connected capacitor 104b.The motor of hoist engine 106 is relative winding A connection inverter 103a when for example being 2 winding motors, and winding B connects inverter 103b relatively.
Car 108 is connected with main rope 109 by balance weight 107, and main rope 109 is located at hoist engine 106, but car 108 rise and fall.
Constitute as control, for example be connected control unit 105a with inverter 103b, carry out the control of inverter at inverter 103a.Be connected control unit 105b at current transformer 102a with current transformer 102b, carry out the control of current transformer.
Motor reel at hoist engine 106 connects rotation detector (rotation sensor) 110, but its output Input Control Element 105a.The operation control of elevator is undertaken by control unit 105a.Speed controlling portion divides according to instruct ω from elevator speed
*With the speed feedback computing torque instruction Tm of rotation sensor 110,1/2 power supply instruction is delivered to the Current Control part of A system, B system respectively.
Be connected current detector 112c and current detector 112d at the outlet side of inverter 103a and the outlet side of inverter 103b, can import its output by control unit 105a.Each feedback current is offered the Current Control part that A is, B is, output voltage instruction Vda
*, Vqa
*, Vdb
*, Vqb
*Each voltage instruction is provided to the PWM control section, and gate signal GATE_A, GATE_B are outputed to inverter 103a, 103b respectively, 2 winding motors of control hoist engine 106.
, such problem below the existence in such elevator control device.Since the deviation of the switch motion of the element of the A winding of the motor of hoist engine 106 and the imbalance of B winding and the accuracy of manufacture, inverter 103a and 103b and produce at output voltage unequal, thereby current imbalance appears in A system and B system.The rotation sensor 110 that detects the motor magnetic pole position is owing to be 1, so, occasion at the such structure of the winding of for example about pulley, adorning A system and B system in the difference according to being constructed to of motor, different in A system with position of magnetic pole in the B system, so, must be at A, B system aligns position of magnetic pole respectively, but produces uneven at output current in the occasion that can not adjust.
As the state being, though, as control circuit electric current is fluidly revised like that in B system and moved then being that the output B of inverter is the occasion that the electric current of inverter fully flows for example according to instruction output A.In the time will in B system, flowing, because this is that needed current value produces deviation with A, so, the generation torque ripple.In addition, when electric current can not fully be exported, self also changed torque instruction.Such state carries out repeatedly, produces extensional vibration, so, the riding comfort variation.
In addition, structure according to motor, occasion for the such structure of the winding that for example dress A is and B is in the difference about pulley, the current imbalance that by A system and B is about produce polarization, so, may vibrate, riding comfort is exerted an influence, or the mechanisms such as bearing breakage of motor rotation axis break down.
Summary of the invention
The present invention makes in order to solve problem as described above, its purpose is to provide a kind of elevator control device, this elevator control gear can improve by a plurality of inverters and drives the decrease in efficiency that the current imbalance of the occasion of multi-winding motors causes, simultaneously, can suppress vibration, improve riding comfort.
In order to achieve the above object, a kind of elevator control device of the present invention, have: the hoist engine that constitutes by the many windings permanent-magnet synchronous electric motor that makes elevator lifting, be used to drive a plurality of inverters and the convertor assembly of above-mentioned many windings permanent-magnet synchronous electric motor, detect the rotation detecting unit of turned position of the axle of above-mentioned many windings permanent-magnet synchronous electric motor, be used to usually to carry out the magnetic pole adjustment unit that magnetic pole is adjusted from the output and the magnetic pole adjustment of above-mentioned rotation detecting unit, wherein this magnetic pole adjustment key element is that above-mentioned permanent-magnet synchronous electric motor is rotated, according to the phase place of induced voltage and definite, by being used to make q shaft current equalization from the output of above-mentioned magnetic pole adjustment unit, thereby make the magnetic flux equalization, control the control unit of above-mentioned inverter and convertor assembly.
According to the present invention, by system's setting current control unit alone at each motor winding, same torque instruction is provided, control the q shaft current equably, make the magnetic flux equalization in each system, thereby can improve the current imbalance of each motor winding system, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration to riding comfort.
In addition, in order to achieve the above object, elevator control gear of the present invention have the hoist engine that constitutes by the multi-winding motor that makes elevator lifting, be used to drive a plurality of inverters of multi-winding motor and convertor assembly, the rotation detecting unit of the turned position of the axle of detection multi-winding motor, and the control unit of control inverter and convertor assembly; It is characterized in that: infer the position of magnetic pole of each system according to the inductance of armature, make with either party's systems compliant ground and revise position of magnetic pole.
According to the present invention, infer the position of magnetic pole of each system according to armature inductance, make both sides' response as one man revise position of magnetic pole, thereby can improve the current imbalance of each motor winding system, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration to riding comfort.
In addition, in order to achieve the above object, elevator control device of the present invention have the hoist engine that constitutes by the multi-winding motor that makes elevator lifting, be used to drive a plurality of inverters of multi-winding motor and convertor assembly, the rotation detecting unit of the turned position of the axle of detection multi-winding motor, and the control unit of control inverter and convertor assembly; It is characterized in that: adjust the magnetic flux of the flow direction of permanent magnet according to the d shaft current, in each winding system, control voltage equably, thereby control the electric current of each system equably.
According to the present invention, adjust the magnetic flux of the flow direction of permanent magnet according to the d shaft current, adjust the magnetic flux in each winding system, control voltage equably, thereby can control the electric current of each system equably, prevent that the abnormal elevator that the decrease in efficiency of inverter causes from stopping, and in addition, can improve the influence of vibration to riding comfort.
In addition, in order to achieve the above object, elevator control device of the present invention have the hoist engine that constitutes by the multi-winding motor that makes elevator lifting, be used to drive a plurality of inverters of multi-winding motor and convertor assembly, the rotation detecting unit of the turned position of the axle of detection multi-winding motor, and the control unit of control inverter and convertor assembly; It is characterized in that: for the direction ground that obtains necessary magnetic flux when the low cruise, in each system magnetic flux is resulted to cancel out each other makes armature supply mobile.
According to the present invention, in order to obtain necessary magnetic flux when the low cruise, the direction that in each system, magnetic flux is resulted to cancel out each other armature supply is flowed, thereby can flow through the electric current of the effect of not accepting idle time, can improve the passenger load maximum deceleration when landing operation such influence idle time and the vibration that produces to the influence of riding comfort.
In addition, in order to achieve the above object, elevator control device of the present invention is characterised in that: have uneven than arithmetic element, comparing unit, and circular unit; This imbalance is than the imbalance ratio of the electric current of each system of arithmetic element computing; This comparing unit relatively should imbalance than the output and the uneven threshold value of arithmetic element; This circular unit is according to the comparative result of this comparing unit, when imbalance surpasses uneven threshold value than the output of arithmetic element it circulated a notice of.
According to the present invention, surpassing uneven occasion, give a warning, thereby can impel the necessity of noting maintenance in the occasion that current imbalance does not improve by the circular unit than threshold value, so, can prevent that the fault that current imbalance causes from stopping.
Description of drawings
Fig. 1 is the signal pie graph that is used to illustrate prior art.
Fig. 2 is the signal pie graph that is used to illustrate the 1st form of implementation of the present invention.
Fig. 3 is the signal pie graph that is used to illustrate the 2nd form of implementation of the present invention.
Fig. 4 is the figure that is used to illustrate the position of magnetic pole waveform example of the 2nd form of implementation of the present invention.
Fig. 5 A, Fig. 5 B are the block diagram that is used to illustrate the 3rd form of implementation of the present invention.
Fig. 6 is the block diagram that is used to illustrate the 4th form of implementation of the present invention.
Fig. 7 is the figure that is used to illustrate the position of magnetic pole waveform example of the 4th form of implementation of the present invention.
Fig. 8 A, Fig. 8 B are the figure that is used to illustrate the magnetic flux that the armature supply of the 4th form of implementation of the present invention produces.
Fig. 9 is the process chart that is used to illustrate the 4th form of implementation of the present invention.
Figure 10 is the signal pie graph that is used to illustrate the 5th form of implementation of the present invention.
Embodiment
One form of implementation of elevator control gear of the present invention is described with reference to the accompanying drawings.In with figure below, same-sign is represented with a part or counterpart.
(the 1st form of implementation)
Fig. 2 illustrates system's configuration example of explanation the 1st form of implementation of the present invention.As shown in the drawing, at power supply 1 current transformer 2a in parallel and current transformer 2b.Connect inverter 3a at current transformer 2a, between current transformer 2a and inverter 3a (for the waveform smoothing) and be connected capacitor 4a.Connect inverter 3b at current transformer 2b, between current transformer 2b and inverter 3b, be connected (for the waveform smoothing) capacitor 4b.Hoist engine 6 is made of 2 winding permanent magnet synchronous motors, and winding A connects inverter 3a relatively, and winding B connects inverter 3b relatively.Motor reel at hoist engine 6 connects rotation detector (rotation sensor) 10, but its output Input Control Element 5a.
Constitute as control, for example be connected control unit 5a with inverter 3b, carry out the control of inverter at inverter 3a.Be connected control unit 5b at current transformer 2a with current transformer 2b, carry out the control of current transformer.At current transformer 2a, 2b, inverter 3a, 3b current detector 12a, 12b, 12c, 12d are set respectively, at direct current component voltage detector 15a, 15b are set respectively, its output can be detected by control unit 5a and control unit 5b.Control unit 5a is connected by communication unit 11 with control unit 5b, can carry out mutual information exchange.
In addition, constitute as control, the output θ that relatively rotates detector 10 adds the adjustment key element by A system, B system respectively.As adjusting key element, when adjusting,,, this fixed value is adjusted key element θ adja, θ adjb input as magnetic pole according to the phase decision fixed value of induced voltage by motor is rotated.In addition, relatively A system, B system will append magnetic pole and adjust θ a, the θ b of key element θ adja, θ adjb and offer 32 phase inversion parts (detecting electric current dq conversion fraction) and 23 phase inversion parts mutually mutually respectively.In addition, the output θ of rotation detector 10 is input to speed detection unit.Obtain the output ω and the speed command ω of speed detection unit
*Poor, its result is outputed to the speed control part.Partly (detect electric current dq conversion fraction) to carry out 3 phases, 2 phase inversion by the detected signal of current detector 12a, 12c by 3 phases, 2 phase inversion.
To offer the Current Control part that A system and B are by what the speed controlling portion branch calculated with coming to the same thing.The current feedback value that current feedback value and the B that obtains torque instruction (instruction of q shaft current) and A system is poor outputs to the Current Control part that respectively is.2 phases, 3 phase inversion are carried out in the output of Current Control part, output to the pwm circuit that respectively is, gate signal GATE_A is outputed to inverter 3a, and the GATE_B signal is outputed to inverter 3b, carry out the control of inverter.Magnetic flux is =L * Iq according to armature inductance L and electric current I q, can make it even in A system and B system.Induced electromotive force when motor rotates is eq=ω , and as being that is identical in the B system at A, then to be at A that B is identical for induced voltage.Therefore, the imbalance of the voltage between terminals Vd of motor disappears in A system and B are, for this reason, motor current becomes even in A system and B system.
And magnitude of voltage Vd, Vq on the 2 phase axles are expressed from the next.
Wherein, R: impedance, L: inductance
P: differential operator, ed, eq: induced electromotive force
As described above, system's setting current control unit alone at each motor winding of many windings permanent magnet synchronous mode motor, same torque instruction is provided, carry out the magnetic pole adjustment, control the q shaft current equably, control magnetic flux equably, thereby can improve the current imbalance of each motor winding system, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration riding comfort.
(the 2nd form of implementation)
Below with reference to Fig. 3 the 2nd form of implementation of the present invention is described.Formation and Fig. 2 of this form of implementation shown in Figure 3 are same, constitute as control, relatively rotate the output θ of detector 10, A system, B system are added magnetic pole respectively adjust key element θ adja, θ adjb, simultaneously, θ a, the θ b that will be at A, magnetic pole correction key element Δ θ a, Δ θ b has appended in B system is provided to 32 phase inversion parts (detecting electric current dq conversion fraction) and 23 phase inversion parts mutually mutually.
Below, the operation method of magnetic pole correction key element Δ θ a, Δ θ b is described.Occasion at permanent magnet synchronous motor, as the relation of position of magnetic pole and armature inductance, known when electric current when flowing with the flow direction equidirectional of magnet, by the magnetic saturation of iron core inductance is reduced, when electric current flowed along the direction with the flow direction orthogonal of magnet, inductance increased.The relation of position of magnetic pole θ and inductance L is represented as shown in Figure 4.Therefore, in the elevator stopped process, A system, B system make ladder (step) ripple towards direction (the A system: θ adja+90 ° direction, B system: θ adjb+90 ° direction) flow through, measure this current response τ a and τ b that shifts to an earlier date 90 ° than the position of magnetic pole of motor rotor relatively respectively.The response constant of motor is represented by τ=L/R.The L of motor and R value for knowing in advance, so, be τ 0=L0/R0 with this value representation.Learn after the mensuration, be the timeconstant a of A system and the timeconstant b of B system.For example, during more near τ 0, make the B response consistent than τ b when establishing timeconstant a with the response that A is.Position of magnetic pole is in advance by snapping to a certain degree near 90 degree, as thinks that 180 degree magnetic poles can not be offset in the manufacturing of motor, then can revise as described below.When the response ratio A that establishes B system as shown in Figure 4 is fast, revise Δ θ b1, measure response once more towards this is shifted to an earlier date 90 ° of directions (b1+90 ° of direction of θ adjb+ Δ θ) towards the direction (as the direction of angle π) that increases the L value.As respond unanimity, then should be worth decision and be correction value.As inconsistent, then before unanimity n time repeatedly, the correction angle n Δ θ b1 decision during with unanimity is correction value Δ θ b.
As described above, by in A system, B system, making the current response of 2 winding permanent magnet synchronous motors as one man revise magnetic pole, thereby the current imbalance of each motor winding system that the adjustment deviation of improving position of magnetic pole produces, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration to riding comfort.
(the 3rd form of implementation)
Below, according to Fig. 5 A, Fig. 5 B the 3rd form of implementation of the present invention is described.The basic comprising of this form of implementation is identical with Fig. 2 basically, but partly appends the magnetic flux amending unit in Current Control, and the Current Control part of change is shown at Fig. 5 A, Fig. 5 B.
Below, A system is described.Torque instruction Tm instructs Iqa as shaft current
*The difference of obtaining with value of feedback Iqa outputs to the PI control section.D axle side is input to a magnetic flux correction arithmetic section 41a with the value of feedback Ida and the Idb of A system and B system respectively.The difference that obtains its output and value of feedback Ida outputs to the PI control section.The PI control of d axle, q axle is input to 2 phases, 3 phase inversion parts.2 phases, 3 phase inversion will output to the PWM part as the voltage instruction of its output by the angle θ a conversion of A system.In B system, also be same formation, the torque instruction input is identical Tm with A, instruction obtains to be input to the PI control section with the difference of value of feedback Iqb as the q shaft current.D axle side is input to d axle magnetic flux correction arithmetic section 41b with the value of feedback Ida and the Idb of A system and B system.The difference that obtains this output and value of feedback Idb outputs to the PI control section.The PI control of d axle, q axle is input to 2 phases, 3 phase inversion parts.2 phases, 3 phase inversion will output to the PWM part as the voltage instruction of its output by the angle θ b conversion of B system.
D axle magnetic flux correction arithmetic section 41 for example carries out size relatively according to the value of feedback Iqa and the Iqb of A system and B system, when B system hour, the value of feedback Idb of B system is flowed towards positive direction, strengthen the magnetic flux with the magnet equidirectional, the voltage that increase is responded to.As one man carry out magnetic flux correction with the magnet equidirectional by the voltage Vq that makes A system and B system, thereby can make electric current even.
In addition, the correction of magnetic flux also can be carried out like this, that is, the voltage that is that makes a bigger side descends, and for example when B system is big, value of feedback Idb is flowed towards negative direction, weakens the magnetic flux with the magnet equidirectional, reduces the voltage of responding to.
As described above, even there is deviation in the magnetic flux of permanent magnet in each system, by adjust the magnetic flux of the flow direction of permanent magnet by the d shaft current, adjust the magnetic flux of each winding system, control voltage equably, thereby can control the electric current of each system equably, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration to riding comfort.
(the 4th form of implementation)
Below, according to Fig. 6~Fig. 9 the present invention's the 4th form of implementation is described.Usually, produce same magnetic flux ground in A system and B system armature supply is flowed, but when moving, become the not too mobile state of electric current under to the lighter state of the load of motor, exert an influence idle time.Idle time P side and the not short circuit of N side make both sides' element disconnect certain hour, the output current of inverter is as enough big, then do not have the waveform distortion of idle time, as when being near zero smaller value handing over, then the influence of idle time makes current waveform not become the distortion of sinusoidal rolling land.This exerts an influence, and vibrates, and the riding comfort of elevator is exerted an influence.Its waveform example is Fig. 7.Current waveform example 1 is a waveform example of accepting the influence of idle time, and current waveform example 2 illustrates the waveform example when electric current is fully flowed.
Below, the formation of this form of implementation is described.Constitute with Fig. 2 same.But, change control and constitute, its controller chassis is illustrated in Fig. 6.The formation of Fig. 2 is partly appended magnetic flux arithmetic section 51 in Current Control relatively, outputs to the current-order of A system and the current-order of B system respectively.The winding of A system and B system being rolled onto the occasion of the formation of 1 iron core, make the direction that produces magnetic flux identical in A system and B system usually, the magnetic flux 1 ( 1= a+ b) of generation necessity as the formation of motor.By the direction that magnetic flux takes place being exported, thereby can flow through enough electric currents with cancelling out each other, obtain the magnetic flux ( 1= a- b) of necessity in A system and B system.
In magnetic flux arithmetic section 51, at input torque instruction Tm, make torque instruction than T1 hour, for example in the occasion of the magnetic flux that needs 1, the current-order output Iqax of A system, produce a, flux reversal part in magnetic flux arithmetic section 51, B system output make resultant flux become the such current-order Iqbx of 1, produce magnetic flux b.That is, the output of A system makes the summation and the consistent such current-order Iqax of torque instruction of the current-order that is with B, produces magnetic flux a (Fig. 8 A, Fig. 8 B).
Fig. 9 illustrates flow chart.The action of magnetic flux arithmetic section 51 is described according to this figure below.At step S801 input torque instruction Tm.At step S802, compare torque instruction Tm and T1.Little as Tm, then advance to step S803.Carry out opposite flux regulator at step S803.At step S2, big as Tm, then advance to step S804, control usually.Like this, when torque instruction Tm than T1 hour, in A system and B system towards the direction generation magnetic flux of offsetting, thereby obtain needed magnetic flux 1.
Producing magnetic flux ground by the direction that as described above A system and B is tied up to counteracting controls, thereby can not accept enough electric currents of the effect of idle time by inverter output, by the current waveform distortion that prevents from idle time to cause, thereby can improve the influence of vibration to riding comfort.
(the 5th form of implementation)
Below, with reference to Figure 10 the 5th form of implementation of the present invention is described.
Basic comprising and Fig. 2 of this form of implementation shown in Figure 10 are same, form the formation that relative Fig. 2 appends display unit.In addition, constitute, append the current imbalance test section as control.
Output signal Ia, the Ib of current detector 12c, 12d are input to absolute value circuit 91a, 91b respectively.The outlet side of absolute value circuit 91a, 91b is connected to filter circuit 92a, 92b, the output average current.
The outlet side of filter circuit is connected to uneven ratio calculating circuit 93, but the ratio of computing A system and B system.The outlet side of uneven ratio calculating circuit 93 is connected to comparison circuit 94, compares with the uneven threshold value that is predetermined, and when surpassing threshold value, outputs to display 16 and gives a warning.Detecting decision in the overcurrent with one-sided inverter is 130% o'clock, threshold value is set to than overcurrent detects low part.For example, as detect when being located at one-sided decline 20%, one-sided increase by 20%, then be provided with 0.66 (=0.8/1.2)<B/A<1.5 (=threshold value such as 1.2/0.8).
Current imbalance is set as described above than the comparing unit of the output of arithmetic element, more above-mentioned arithmetic element and uneven threshold value, and display unit, in the occasion that surpasses uneven threshold value, to above-mentioned display unit circular, thereby can can't help overcurrent produces and to abend, the occasion of not improving at current imbalance, can urge the necessity of noting maintenance, so, can prevent that the fault that current imbalance causes from stopping.
As above explicable, according to the present invention, system's setting current control unit alone at each motor winding of multi-winding motor, same torque instruction is provided, control magnetic flux equably, thereby can improve the current imbalance of each motor winding system, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration to riding comfort.
In addition, according to the present invention, in multi-winding motor, make current response as one man revise position of magnetic pole to each system, thereby the current imbalance of each motor winding system that the adjustment skew that can improve position of magnetic pole causes, prevent abending of elevator that the decline of the efficient of inverter causes, in addition, can improve the influence of vibration riding comfort.
In addition, according to the present invention, even there is deviation in each system at the magnetic flux of permanent magnet, adjust the magnetic flux of the flow direction of permanent magnet according to the d shaft current, adjust the magnetic flux in each winding system, control voltage equably, thereby can control the electric current of each system equably, prevent that the abnormal elevator that the decrease in efficiency of inverter causes from stopping, and in addition, can improve the influence of vibration to riding comfort.
In addition, according to the present invention, the direction ground control that in each system, magnetic flux is resulted to cancel out each other, thereby can not accept enough electric currents of the effect of idle time by inverter output, prevent that the current waveform that causes idle time is out of shape, thereby can improve the influence of vibration riding comfort.
In addition, according to the present invention, surpass uneven occasion at the current imbalance ratio than threshold value, give a warning by the circular unit, do not abend thereby can not produce,, can urge the necessity of noting maintenance in the occasion that current imbalance does not improve by overcurrent, so, can prevent that the fault that current imbalance causes from stopping.
Claims (2)
1. elevator control device has:
The hoist engine that constitutes by the many windings permanent-magnet synchronous electric motor that makes elevator lifting,
Be used to drive a plurality of inverters and the convertor assembly of above-mentioned many windings permanent-magnet synchronous electric motor,
Detect the rotation detecting unit of turned position of the axle of above-mentioned many windings permanent-magnet synchronous electric motor,
Be used to will usually carry out the magnetic pole adjustment unit that magnetic pole is adjusted from the output of above-mentioned rotation detecting unit and magnetic pole adjustment, wherein to adjust key element be that above-mentioned permanent-magnet synchronous electric motor is rotated to this magnetic pole, according to the phase place of induced voltage and definite,
By being used to make q shaft current equalization, thereby make the magnetic flux equalization, control the control unit of above-mentioned inverter and convertor assembly from the output of above-mentioned magnetic pole adjustment unit.
2. elevator control device according to claim 1 is characterized in that: have uneven than arithmetic element, comparing unit, and circular unit;
This imbalance is than the imbalance ratio of the electric current of each motor winding of arithmetic element computing;
This comparing unit relatively should imbalance than the output and the uneven threshold value of arithmetic element;
This circular unit is according to the comparative result of this comparing unit, when imbalance surpasses uneven threshold value than the output of arithmetic element it circulated a notice of.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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JP2002182596A JP4146172B2 (en) | 2002-06-24 | 2002-06-24 | Elevator control device |
JP182596/2002 | 2002-06-24 |
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CN2006101321895A Division CN1927686B (en) | 2002-06-24 | 2003-06-20 | Elevator control device |
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CN1557045A CN1557045A (en) | 2004-12-22 |
CN1310420C true CN1310420C (en) | 2007-04-11 |
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CN2006101321895A Expired - Lifetime CN1927686B (en) | 2002-06-24 | 2003-06-20 | Elevator control device |
CNB038010275A Expired - Lifetime CN1310420C (en) | 2002-06-24 | 2003-06-20 | Control device of elevator |
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KR (1) | KR100574265B1 (en) |
CN (2) | CN1927686B (en) |
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---|---|---|---|---|
JP2005247574A (en) * | 2004-03-08 | 2005-09-15 | Mitsubishi Electric Corp | Elevator control device |
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Also Published As
Publication number | Publication date |
---|---|
TW593113B (en) | 2004-06-21 |
TW200400910A (en) | 2004-01-16 |
CN1927686B (en) | 2011-02-09 |
CN1557045A (en) | 2004-12-22 |
KR20040019405A (en) | 2004-03-05 |
JP2004032849A (en) | 2004-01-29 |
JP4146172B2 (en) | 2008-09-03 |
KR100574265B1 (en) | 2006-04-27 |
WO2004001952A1 (en) | 2003-12-31 |
CN1927686A (en) | 2007-03-14 |
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