Method and system for reconnecting inverter to rotating motors

US 4,734,634 A
Filed: 11/28/1986
Issued: 03/29/1988
Est. Priority Date: 09/05/1984
Status: Expired due to Term

First Claim

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1. A method of reconnecting to an inertially rotating motor an inverter disconnected from the motor during powered operation of the motor and inverter, comprising the steps of:

(a) detecting a power failure or a motor accident condition causing the inverter to be disconnected from the powered motor and resulting in inertial rotation of the motor at a reduced speed due to loss of power from the powering inverter therefrom;

(b) detecting inverter current;

(c) restarting the inverter at an increased frequency and reduced voltage level to provide to the rotating motor a restarting voltage having a frequency higher than a frequency corresponding to the speed of inertial rotation of the motor and a restarting voltage level lower than a rated voltage of the motor;

(d) generating a first command signal F_S1 for restarting said inverter frequency, generating a second command signal F_S2 for decreasing inverter frequency after passage of a predetermined time period from generation of said first command signal F_S1, generating a third command signal F_S3 for maintaining inverter frequency when detected inverter current drops below a predetermined current value, generating a fourth command signal F_S4 for increasing inverter frequency when a ratio of inverter voltage level to inverter frequency reaches a predetermined value, generating a fifth command signal F_S5 for controlling inverter frequency when inverter frequency and voltage level both attain predetermined values therefor at the predetermined ratio thereof;

(e) generating a first voltage command signal V_S1 for generation of an inverter voltage level by said inverter after passage of a second predetermined time period from generation of said first command signal F_S1, generating a second voltage command signal V_S2 for controlling said inverter voltage level after passage of a third predetermined time period from generation of said first voltage command signal V_S1, generating a third voltage command signal V_S3 for increasing inverter voltage level when the detected inverter current drops below said predetermined current value, generating a fourth voltage command signal V_S4 for increasing said inverter voltage level when the ratio of inverter voltage level to inverter frequency reaches said predetermined value thereof, and generating a fifth inverter voltage command V_S5 for controlling inverter voltage level when inverter frequency and voltage level both attain said predetermined values therefor at the predetermined ratio thereof;

(f) outputting a first voltage representative of a first inverter frequency starting signal for restarting the inverter at a predetermined starting frequency in response to the first frequency command signal F_S1, outputting a second voltage representative of a second inverter frequency decreasing signal for gradually decreasing the frequency of the restarted inverter in response to the second frequency command signal F_S2, outputting a third voltage representative of a third inverter frequency maintaining signal for maintaining the decreasing inverter frequency at a constant value in response to the third frequency command signal F_S3, outputting a fourth voltage representative of a fourth inverter frequency increasing signal for increasing the maintained frequency in response to the fourth frequency command signal F_S4, and outputting a fifth voltage representative of a fifth inverter frequency controlling signal for steadily controlling inverter frequency in response to the fifth frequency command signal F_S5 ; and

(g) sequentially generating pulse-width-modulated inverter gate signals to activate the inverter in response to the first, second, third, fourth and fifth voltages representative of inverter frequencies and to the first, second, third, fourth and fifth inverter voltage command signals.

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Abstract

When an inverter is disconnected from a rotating motor due to power failure or motor accident, it is necessary to connect the inverter power again to the rotating motor by the inertia force in order to keep the motor rotating. To achieve the above reconnection, the inverter is controlled in accordance with open-loop control method, without use of any motor speed detecting means, thus improving control response speed. In reconnection, the inverter is started at a frequency higher than the rotating motor speed and at a voltage lower than the rated value; when a predetermined time has elapsed after the starting voltage was applied to the motor, only the frequency is decreased; when inverter driving current drops below a predetermined value, the frequency is held and only the voltage is increased until the voltage-to-frequency ratio reaches a predetermined value.

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6 Claims

1. A method of reconnecting to an inertially rotating motor an inverter disconnected from the motor during powered operation of the motor and inverter, comprising the steps of:
- (a) detecting a power failure or a motor accident condition causing the inverter to be disconnected from the powered motor and resulting in inertial rotation of the motor at a reduced speed due to loss of power from the powering inverter therefrom;
  
  (b) detecting inverter current;
  
  (c) restarting the inverter at an increased frequency and reduced voltage level to provide to the rotating motor a restarting voltage having a frequency higher than a frequency corresponding to the speed of inertial rotation of the motor and a restarting voltage level lower than a rated voltage of the motor;
  
  (d) generating a first command signal F_S1 for restarting said inverter frequency, generating a second command signal F_S2 for decreasing inverter frequency after passage of a predetermined time period from generation of said first command signal F_S1, generating a third command signal F_S3 for maintaining inverter frequency when detected inverter current drops below a predetermined current value, generating a fourth command signal F_S4 for increasing inverter frequency when a ratio of inverter voltage level to inverter frequency reaches a predetermined value, generating a fifth command signal F_S5 for controlling inverter frequency when inverter frequency and voltage level both attain predetermined values therefor at the predetermined ratio thereof;
  
  (e) generating a first voltage command signal V_S1 for generation of an inverter voltage level by said inverter after passage of a second predetermined time period from generation of said first command signal F_S1, generating a second voltage command signal V_S2 for controlling said inverter voltage level after passage of a third predetermined time period from generation of said first voltage command signal V_S1, generating a third voltage command signal V_S3 for increasing inverter voltage level when the detected inverter current drops below said predetermined current value, generating a fourth voltage command signal V_S4 for increasing said inverter voltage level when the ratio of inverter voltage level to inverter frequency reaches said predetermined value thereof, and generating a fifth inverter voltage command V_S5 for controlling inverter voltage level when inverter frequency and voltage level both attain said predetermined values therefor at the predetermined ratio thereof;
  
  (f) outputting a first voltage representative of a first inverter frequency starting signal for restarting the inverter at a predetermined starting frequency in response to the first frequency command signal F_S1, outputting a second voltage representative of a second inverter frequency decreasing signal for gradually decreasing the frequency of the restarted inverter in response to the second frequency command signal F_S2, outputting a third voltage representative of a third inverter frequency maintaining signal for maintaining the decreasing inverter frequency at a constant value in response to the third frequency command signal F_S3, outputting a fourth voltage representative of a fourth inverter frequency increasing signal for increasing the maintained frequency in response to the fourth frequency command signal F_S4, and outputting a fifth voltage representative of a fifth inverter frequency controlling signal for steadily controlling inverter frequency in response to the fifth frequency command signal F_S5 ; and
  
  (g) sequentially generating pulse-width-modulated inverter gate signals to activate the inverter in response to the first, second, third, fourth and fifth voltages representative of inverter frequencies and to the first, second, third, fourth and fifth inverter voltage command signals.

2. Apparatus for reconnecting to an inertially rotating motor an inverter disconnected from the motor during powered operation of the motor and inverter, comprising:
- (a) means for detecting a power failure or a motor accident condition causing the inverter to be disconnected from the powered motor and resulting in inertial rotation of the motor at a reduced speed due to loss of power from the powering inverter;
  
  (b) current detecting means for detecting inverter current;
  
  (c) microcomputer means for restarting the inverter at an increased frequency and reduced voltage level to provide to the rotating motor a restarting voltage having a frequency higher than a frequency corresponding to the speed of inertial rotation of the motor and a restarting voltage level lower than a rated voltage of the motor;
  
  (d) said microcomputer means responsive to said inverter current detecting means and operable for generating a first command signal F_S1 for restarting said inverter frequency, generating a second command signal F_S2 for decreasing inverter frequency after passage of a predetermined time period from generation of said first command signal F_S1, generating a third command signal F_S3 for maintaining inverter frequency when detected inverter current drops below a predetermined current value, generating a fourth command signal F_S4 for increasing inverter frequency when a ratio of inverter voltage level to inverter frequency reaches a predetermined value, generating a fifth command signal F_S5 for controlling inverter frequency when inverter frequency and voltage level both attain predetermined values therefor at the predetermined ratio thereof, andsaid microcomputer means further operable for generating a first voltage command signal V_S1 for generation of an inverter voltage level by said inverter after passage of a second predetermined time period from generation of said first command signal F_S1, generating a second voltage command signal V_S2 for controlling said inverter voltage level after passage of a third predetermined time period from generation of said first voltage command signal V_S1, generating a third voltage command signal V_S3 for increasing inverter voltage level when the detected inverter current drops below said predetermined current value, generating a fourth voltage command signal V_S4 for increasing said inverter voltage level when the ratio of inverter voltage level to inverter frequency reaches said predetermined value thereof, and generating a fifth inverter voltage command V_S5 for controlling inverter voltage level when inverter frequency and voltage level both attain said predetermined values therefor at the predetermined ratio thereof;
  
  (e) frequency controlling means responsive to said microcomputer means for controlling inverter frequencies, said controlling means operable for outputting a first voltage representative of a first inverter frequency starting signal for restarting the inverter at a predetermined starting frequency in response to the first frequency command signal F_S1, outputting a second voltage representative of a second inverter frequency decreasing signal for gradually decreasing the frequency of the restarted inverter in response to the second frequency command signal F_S2, outputting a third voltage representative of a third inverter frequency maintaining signal for maintaining the decreasing inverter frequency at a constant value in response to the third frequency command signal F_S3, outputting a fourth voltage representative of a fourth inverter frequency increasing signal for increasing the maintained frequency in response to the fourth frequency command signal F_S4, and outputting a fifth voltage representative of a fifth inverter frequency controlling signal for steadily controlling inverter frequency in response to the fifth frequency command signal F_S5 ; and
  
  (f) pulse-width-modulating means responsive to said microcomputer means and to said frequency controlling means for sequentially generating pulse-width-modulated inverter gate signals to activate the inverter in response to the first, second, third, fourth and fifth voltages representative of inverter frequencies and to the first, second, third, fourth and fifth inverter voltage command signals.
- View Dependent Claims (3, 4, 5, 6)
- - 3. An apparatus for reconnecting an inverter to a motor as set forth in claim 2, wherein said frequency controlling means comprises:
    - (a) an integrating circuit including a capacitor for charging DC voltages representative of inverter frequencies;
      
      (b) an initial inverter frequency presetting device for outputting a voltage to charge the capacitor;
      
      (c) a first capacitor charging resistor having a relatively short time constant with respect to the capacitor and connected between said initial inverter frequency presetting device and the capacitor for quickly charging the capacitor in response to the first command signal F_S1 ;
      
      (d) a second capacitor charging resistor having a relatively long time constant with respect to the capacitor and connected in parallel with said first capacitor charging resistor and between a negative power supply and the capacitor for further gently charging the capacitor in response to the first command signal F_S1 after the capacitor has been charged up quickly by the voltage outputted from said initial inverter frequency presetting device;
      
      (e) a third capacitor discharging resistor having a medium time constant with respect to the capacitor and connected between a positive power supply and the capacitor for discharging the capacitor in response to the second command signal F_S2 ;
      
      said third resistor being disconnected from the capacitor for holding electric charge of the capacitor at a constant value in response to the third command signal F_S3 ; and
      
      (f) a fourth capacitor charging resistor having a medium time constant with respect to the capacitor and connected between said initial inverter frequency presetting device and the capacitor for charging the capacitor in response to the fourth command signal F_S4.
  - 4. An apparatus for reconnecting an inverter to a motor as set forth in claim 2, wherein said pulse-width-modulating means comprises:
    - (a) a voltage-frequency converter responsive to said frequency controlling means for outputting signals having frequencies proportional to voltages developed across a capacitor;
      
      (b) a triangular-wave signal generator responsive to said frequency controlling means for generating triangular-wave signals having frequencies an integer times higher than that of the signals from said voltage-frequency converter;
      
      (c) a sine-wave signal generator responsive to said microcomputer means and said voltage-frequency converter for generating sine-wave signals having frequencies equal to the signals from said voltage-frequency converter and amplitudes adjusted according to the inverter voltage command signals;
      
      (d) a comparator responsive to said triangular-wave signal generator and said sine-wave signal generator for comparing the voltages thereof to determine effective inverter voltages in accordance with a pulse width modulation method; and
      
      (e) a gate logic circuit responsive to said comparator for outputting gate signals in sequence to the inverter in such a way that inverter frequencies and inverter voltages are both controlled in accordance with the pulse width modulation method.
  - 5. An apparatus for reconnecting an inverter to a motor as set forth in claim 2, which further comprises:
    - (a) a voltage detector for detecting a DC supply voltage of the inverter and outputting an overvoltage signal;
      
      to said microcomputer means when the DC supply voltage is excessively high; and
      
      (b) a plurality of switching elements connected between said pulse-width modulating means and the inverter, said switching elements being opened in response to an inverter disable signal indicative of DC supply overvoltage outputted from said microcomputer means.
  - 6. An apparatus for reconnecting an inverter to a motor as set forth in claim 2, which further comprises:
    - (a) an overcurrent protector responsive to said current detecting means for outputting an inverter overcurrent signal when inverter current is excessively large; and
      
      (b) a comparison point provided in said frequency controlling means for subtracting a voltage level of the inverter overcurrent signal from the voltages representative of inverter frequencies in order to adjustably control the voltages representative of inverter frequencies.

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Current Assignee
Kabushiki Kaisha Meidensha
Original Assignee
Kabushiki Kaisha Meidensha
Inventors
Yasukawa, Kuniake, Kito, Yasutami
Primary Examiner(s)
Smith, Jr., David

Application Number

US06/938,321
Time in Patent Office

487 Days
Field of Search

318/778, 318/807-811
US Class Current

318/778
CPC Class Codes

H02P 1/30 by progressive increase of ...

H02P 29/025 the fault being a power int...

Method and system for reconnecting inverter to rotating motors

First Claim

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Abstract

45 Citations

6 Claims

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Method and system for reconnecting inverter to rotating motors

First Claim

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Accused Products

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Abstract

45 Citations

6 Claims

Specification

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Solutions

Use Cases

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