JP5545661B2 - Method for preventing reverse rotation of single-phase motor and single-phase motor control circuit - Google Patents

Description

  The present invention relates to a single-phase motor reverse rotation prevention method and a single-phase motor control circuit for preventing reverse rotation of a single-phase motor having an auxiliary winding.

  Some cutting machines (shredders) use a phase separation start type equipped with a mechanical governor switch or a capacitor start capacitor induction type single phase motor as a drive source of the cutting mechanism. In such a shredder, at the time of start-up, in the split-phase start type, current is passed through the main winding of the single-phase motor, and current is passed through the auxiliary winding through a mechanical governor switch. Thereby, when the rotational speed of the motor rises, the mechanical governor switch is turned off, the current of the auxiliary winding is cut off, and thereafter the cutting mechanism is driven only by the current flowing through the main winding.

  Patent Document 1 discloses a phase-separated starting single-phase motor control circuit that is used in a cutting machine and performs drive control of a phase-separated starting single-phase motor having an auxiliary winding for starting. An energizing means for energizing the auxiliary winding for a first time after power-on, a means for detecting an induced voltage generated in the auxiliary winding after the energizing means is energized for the first time, and the induced voltage detected by the means is a predetermined voltage. And a means for energizing the auxiliary winding for a second time when it is determined that the determination means falls below a predetermined voltage. Chattering due to insufficient cutting ability does not occur, and the cutter does not deform or spill.

Japanese Patent No. 4446955

In the shredder, as shown in FIG. 5A, when a large amount of paper 15 is loaded, the large amount of paper 15 is bitten by two shredding cutters 2 and 2, and a single phase of a phase separation start type or a capacitor start capacitor induction type The motor 1 stops instantaneously (FIG. 5B). After stopping instantaneously, due to the elasticity of the shredder mechanism (such as the shredding cutter 2 and the frame) and the characteristics of the single-phase motor 1, reverse rotation starts (FIG. 5C), and the paper cannot be shredded. Moreover, since the time to reverse rotation is short, the overload detection function installed in the shredder does not operate, and the shredder control device cannot recognize that it is in a state where shredding is not possible, and the runaway state There is a problem of becoming.
As a result, the rotation direction of the single-phase motor 1 reverses in a short time as shown in FIG. 6A, and the open / close state of the mechanical governor switch changes as shown in FIG. 6B.

The present invention has been made in view of the circumstances as described above, and provides a method for preventing reverse rotation of a single-phase motor that can prevent reverse rotation and runaway when an excessive load is applied. Objective.
The second invention aims to provide a single-phase motor control circuit in which the single-phase motor does not reversely run out of control when an excessive load is applied.

  A method for preventing reverse rotation of a single-phase motor according to a first aspect of the present invention is a single-phase including an auxiliary winding that is a phase-separated starting type having an auxiliary winding for starting, or a capacitor starting capacitor inductive type having a starting capacitor for starting. A method for preventing reverse rotation of the motor, wherein after the power is turned on, the auxiliary winding for start-up (phase separation start type) or the start capacitor (capacitor start capacitor induction type) is energized for a predetermined time, and then the auxiliary winding Detects the induced voltage generated in the wire, determines whether the detected induced voltage is lower than the predetermined voltage, and if it is determined that the induced voltage is lower than the predetermined voltage, is an overcurrent flowing through the single-phase motor? The start auxiliary winding (phase-separated start type) or the start capacitor (capacitor start capacitor inductive type) is energized for a time required to determine whether or not.

  A single-phase motor control circuit according to a second aspect of the present invention drives a single-phase motor having an auxiliary winding that is a phase-separated starting type having an auxiliary winding for starting, or a capacitor starting capacitor induction type having a starting capacitor for starting. In a single-phase motor control circuit that performs control, energizing means for energizing the auxiliary winding for start-up (phase separation start type) or the start capacitor (capacitor start capacitor induction type) for a predetermined time after power-on, and the energization means Overcurrent determining means for determining whether or not an overcurrent flows through the single-phase motor after being energized for a predetermined time, and means for detecting an induced voltage generated in the auxiliary winding after the energizing means is energized for a predetermined time Determining means for determining whether the induced voltage detected by the means is lower than a predetermined voltage; and when the determining means determines that the induced voltage is lower than the predetermined voltage, Time required above, characterized in that it comprises a means for energizing the auxiliary winding for the start (phase separation-starting) or said starting capacitor (capacitor starting capacitor induction).

In the method for preventing reverse rotation of the single-phase motor according to the first invention and the single-phase motor control circuit according to the second invention, the single-phase motor control circuit includes a phase-separated starting type having an auxiliary winding for starting, or The drive control of the single phase motor provided with the auxiliary winding which is a capacitor start capacitor induction type with the start capacitor is performed. After the power is turned on, the energizing means energizes the auxiliary winding for starting (phase separation starting type) or the starting capacitor (capacitor starting capacitor induction type) for a predetermined time, and the overcurrent determining means energizes the energizing means for a predetermined time. Then, it is determined whether or not an overcurrent flows through the single-phase motor. The detecting means detects the induced voltage generated in the auxiliary winding after the energizing means is energized for a predetermined time, and the determining means determines whether or not the detected induced voltage is lower than the predetermined voltage. When the determining means determines that the voltage is lower than the predetermined voltage, the energizing means is a starting auxiliary winding (phase-separated starting type) or a starting capacitor (capacitor starting capacitor) for a time required for the overcurrent determination of the overcurrent determining means. Energize the induction type).
Thereby, even when the single-phase motor provided with the auxiliary winding starts to reversely rotate at the time of overload, the overcurrent can continue to flow, and the overcurrent determination means can determine this overcurrent. The power supply can be shut off, and the single-phase motor does not continue to rotate backward.

  According to the reverse rotation prevention method for a single phase motor according to the present invention, it is possible to realize a reverse rotation prevention method for a single phase motor capable of preventing reverse rotation and runaway when an excessive load is applied.

  According to the single-phase motor control circuit of the second invention, it is possible to realize a single-phase motor control circuit in which the single-phase motor does not reversely rotate and run away when an excessive load is applied.

It is a block diagram which shows schematic structure of embodiment of the reverse rotation prevention method of a single phase motor which concerns on this invention, and a single phase motor control circuit. It is a block diagram which shows the detailed structure of the capacitor | condenser starting capacitor induction type single phase motor control circuit shown in FIG. It is a flowchart which shows the operation example of the single phase motor control circuit which concerns on this invention, and the example of the reverse rotation prevention method of the single phase motor which concerns on this invention. It is a timing chart which shows the operation example of the single phase motor control circuit which concerns on this invention. It is explanatory drawing which shows the operation example of the conventional single phase motor. It is a timing chart which shows the operation example of the conventional single phase motor.

Hereinafter, the present invention will be described with reference to the drawings illustrating embodiments thereof.
FIG. 1 is a block diagram showing a schematic configuration of an embodiment of a method for preventing reverse rotation of a single phase motor and a single phase motor control circuit according to the present invention.
This single-phase motor control circuit is used for a shredder, and an AC power supply 10 is connected to the shredder control device 14, and the shredder control device 14 performs on / off control of the relay 13, whereby the power supply of the single-phase motor 1. ON / OFF control. The single-phase motor 1 is a capacitor starting capacitor induction type motor.

  One terminal of the AC power supply 10 is connected to one terminal of the relay 13 via the current detector 12, and the other terminal of the relay 13 is connected to the main winding 4 of the single-phase motor 1, the capacitor 8, Each one of the terminals 9 is connected. The other terminal of the main winding 4 is connected to the other terminal of the AC power supply 10, and the other terminal of the capacitor 8 is connected to one terminal of the governor switch 16.

The detection signal of the current detector 12 is supplied to the overcurrent determination device 11 in the shredder control device 14, and the overcurrent determination device 11 turns on the relay 13 when determining the overcurrent based on the supplied detection signal. Turn off.
The other terminals of the governor switch 16 and the capacitor 9 are connected to one terminal of the auxiliary winding 5 of the single-phase motor 1, and the other terminal of the auxiliary winding 5 is connected to the other terminal of the single-phase AC power supply 10. It is connected.

FIG. 2 is a block diagram showing a detailed configuration of the single-phase motor control circuit shown in FIG.
This single-phase motor control circuit is electronic, and an AC power supply 10 is provided between terminals U and V. The terminals U and V are connected to both ends of the main winding 4 of the single-phase motor 1. The other terminal of the capacitor 8 is connected to the terminal X of the electronic governor switch 16, and the other terminal of the AC power supply 10 is connected to the terminal Y of the governor switch 16. The terminals X and Y are connected to both ends of the auxiliary winding 5 of the single-phase motor 1 via the terminals X1 and Y1 of the governor switch 16. The other terminal of the capacitor 9 is connected to the terminal X1.

The governor switch 16 has a control power supply circuit 20 connected between the terminals X and Y, and the control power supply circuit 20 converts the AC power supply to a control DC power supply Vcc and outputs it.
The terminal X is connected to one terminal of a resistor 7b and a triac (triode AC switch) (energizing means, energizing means) 7, and the other terminal of the resistor 7b is connected to a phototriac (energizing means, energizing means). 7a is connected to one terminal on the secondary side, and the other terminal on the secondary side is connected to the gate of the triac 7. The other terminal of the triac 7 is connected to the terminal X1.

  One terminal of a resistor 31 (detecting means) is connected between the other terminal of the triac 7 and the terminal X1, and the other terminal is connected to an anode of a diode (detecting means) 32. The cathode of the diode 32 is connected to the cathode of the Zener diode 33, one terminal of the resistor 34, and the anode of the electrolytic capacitor (detecting means) 35. The anode of the Zener diode 33, the other terminal of the resistor 34, and the electrolytic capacitor The cathode of 35 is grounded.

The anode voltage E2 of the electrolytic capacitor 35 is given to the minus terminal of the comparator (determination means) 41, and the voltage divider E1 by the resistors 21 and 22 of the DC power supply Vcc is given to the plus terminal of the comparator 41.
The output terminal of the comparator 41 is connected to the DC power source Vcc through a resistor (energizing means, energizing means) 42, and the negative terminal of the comparator (energizing means, energizing means) 51 through a resistor (energizing means, energizing means) 43. It is connected to the anode of an electrolytic capacitor (energizing means, energizing means) 45. The cathode of the electrolytic capacitor 45 is grounded.

The anode of the diode 44 is connected to the output terminal of the comparator 41, and the cathode is connected to the anode of the electrolytic capacitor 45.
The plus terminal of the comparator 51 is given a voltage division E1 by the resistors 21 and 22 of the DC power source Vcc, and its output terminal is connected to the DC power source Vcc through the primary side of the phototriac 7a and the resistor 52.

The operation of the single-phase motor control circuit having such a configuration and the method for preventing the reverse rotation of the single-phase motor will be described below with reference to the flowchart shown in FIG.
When the relay 13 is turned on and the power is turned on (S 1), AC power is supplied between the terminals U and V and between the terminals X and Y, whereby an AC current Im flows through the main winding 4. When AC power is supplied between the terminals X and Y of the governor switch 16, the control power circuit 20 converts the AC power into DC power Vcc and outputs it, and the voltage divided by the resistors 21 and 22 of the DC power Vcc. E1 is given to each plus terminal of the comparators 41 and 51.

  At this time, since the electrolytic capacitor 35 is not charged, the voltage E2 input to the negative terminal of the comparator 41 is E2 <E1, and the output voltage E3 of the comparator 41 is at the H level. Therefore, a charging current flows from the DC power source Vcc through the resistors 42 and 43 and the diode 44, and the charging voltage (anode voltage) E4 of the capacitor 45 increases.

  When the charging voltage E4 of the capacitor 45 rises and E4> E1, the output voltage E5 of the comparator 51 becomes L level, a current flows from the DC power source Vcc through the resistor 52 to the primary side of the phototriac 7a, and the phototriac The secondary side of 7a becomes conductive. As a result, the gate current If flows to the gate of the triac 7 through the resistor 7b, the triac 7 becomes conductive, the governor switch 16 is turned on (S3), and the alternating current Ia starts to flow in the auxiliary winding 5, and the single-phase motor 1 starts.

When the triac 7 is turned on, a current flows through the resistor 31 and the diode 32 to the parallel circuit of the Zener diode 33, the resistor 34, and the electrolytic capacitor 35, the electrolytic capacitor 35 starts to be charged, and time measurement for a predetermined time T1 is started (S5). ). The charge voltage (anode voltage) E2 rises until it is clamped by the Zener voltage of the Zener diode 33. In the middle of the rise, the charge voltage is inverted to E2> E1.
When E2> E1 and the diode 32 is in the cut-off state (when the alternating current Im is negative), the electrolytic capacitor 35 is discharged through the resistor 34, but the charge voltage E2 is Never fall below E1.

When the charging voltage E2 is inverted to E2> E1, the output voltage E3 of the comparator 41 becomes L level, a discharging current flows from the electrolytic capacitor 45 through the resistor 43, and the charging voltage E4 drops. When the charging voltage E4 drops and reverses to E4 <E1 and the output voltage E5 of the comparator 51 becomes H level, the time measurement for the predetermined time T1 is completed (S7), and the current flowing to the primary side of the phototriac 7a is It is interrupted and the secondary side of the phototriac 7a becomes non-conductive.
As a result, the governor switch 16 is turned off (S9), and the gate current If of the triac 7 is cut off, so that the triac 7 becomes non-conductive and the alternating current Ia flowing through the auxiliary winding 5 is cut off. Further, the charging voltage E2 of the electrolytic capacitor 35 drops, the electrolytic capacitor 45 is further discharged, and the time count for the predetermined time T1 is reset (S11).

In this state, the single-phase motor 1 continues to rotate only with the current Im flowing through the main winding 4 because the rotational speed has risen above a predetermined rotational speed. As a result, an induced voltage corresponding to the rotational speed of the single-phase motor 1 is induced in the auxiliary winding 5 from which the current Ia is cut off.
When the triac 7 is turned off, the charging voltage E2 of the electrolytic capacitor 35 drops, but E2> E1 is maintained by the induced voltage applied through the resistor 31 and the diode 32.

When the single-phase motor 1 operating with the current Im flowing through the main winding 4 exceeds the shredding capability and becomes overloaded during shredding of the paper, the rotational speed is reduced and induced in the auxiliary winding 5. The induced voltage is reduced.
When the induced voltage induced in the auxiliary winding 5 falls below a predetermined voltage (S13), the charging current is not supplied to the electrolytic capacitor 35, and the electrolytic capacitor 35 is discharged through the resistor 34. As a result, E2 <E1 is inverted, and the output voltage E3 of the comparator 41 starts to rise. As a result, a charging current starts to flow from the DC power source Vcc to the electrolytic capacitor 45 through the resistors 42 and 43 and the diode 44, and the charging voltage E4 of the electrolytic capacitor 45 increases.
When the induced voltage does not drop below the predetermined voltage (S13) and the relay 13 is turned off and the power is turned off (S15), the operation of the single-phase motor 1 is terminated.

When the charging voltage E4 of the electrolytic capacitor 45 is inverted to E4> E1, the output voltage E5 of the comparator 51 becomes L level, a current flows from the DC power source Vcc through the resistor 52 to the primary side of the phototriac 7a, and the phototriac 7a The secondary side of is conductive. As a result, the gate current If flows to the gate of the triac 7 through the resistor 7b, the triac 7 becomes conductive, and the governor switch 16 is turned on (S17).
When the governor switch 16 is turned on, the alternating current Ia begins to flow through the auxiliary winding 5 and the output torque of the single-phase motor 1 increases. However, if the shredder cannot shred the paper, the current Im flowing through the main winding 4 Will increase.

When the triac 7 is turned on, a current flows through the resistor 31 and the diode 32 to the parallel circuit of the Zener diode 33, the resistor 34, and the electrolytic capacitor 35, and the electrolytic capacitor 35 is charged. As a result, the charging voltage E2 rises until it is clamped by the Zener voltage of the Zener diode 33, but at time t6 during the rise, the charging voltage E2 is inverted to E2> E1.
When E2> E1 and the diode 32 is in the cut-off state (when the alternating current Im is negative), the electrolytic capacitor 35 is discharged through the resistor 34, but the charge voltage E2 is Never fall below E1.

When the charging voltage E2 is inverted to E2> E1, the output voltage E3 of the comparator 41 becomes L level, a discharging current flows from the electrolytic capacitor 45 through the resistor 43, and the charging voltage E4 drops. When the charging voltage E4 drops and reverses to E4 <E1, and the output voltage E5 of the comparator 51 becomes H level, the current flowing to the primary side of the phototriac 7a is cut off, and the secondary side of the phototriac 7a is non-conducting And the governor switch 16 is turned off.
In the above operation, the time from when the charging voltage E4 is inverted to E4> E1 to when it is re-inverted to E4 <E1 is whether or not the overcurrent detector 11 has an overcurrent flowing through the single-phase motor 1. The time constants of the electrolytic capacitor 45 and the resistor 43 are determined so as to be longer than the time required to determine

When the governor switch 16 is turned on (S17) and the shredder cannot shred the paper even if the alternating current Ia flows through the auxiliary winding 5, the current Im flowing through the main winding 4 increases. The single-phase motor 1 starts to reversely rotate due to the reaction force due to the elasticity of the mechanism (such as a chopping cutter or a frame), and then the current Im decreases. Even in this case, the governor switch 16 remains on (S17) until the overcurrent determiner 11 can determine the overcurrent (S19).
When the overcurrent determiner 11 determines that the current is an overcurrent (S19), the relay 13 is turned off, the power source of the single-phase motor 1 is turned off (S21), and the shredder operation is terminated.

4A, the rotation direction of the single-phase motor 1 is reversed, but the mechanical governor switch is kept on (closed) as shown in FIG. 4B. 1 stops. Thereby, it can prevent that the single phase motor 1 continues reverse rotation, and can notify a user that the malfunction occurred in the shredder.
In the present embodiment, the case where the single-phase motor 1 is a capacitor start capacitor induction type motor has been described. However, the single-phase motor 1 has a configuration in which the capacitors 8 and 9 are not present in FIGS. Even in the case of the type motor, other configurations and operations are the same as those described above.

1 Single-phase motor 4 Main winding 5 Auxiliary winding 7 Triac (energizing means, energizing means)
7a Phototriac (energizing means, energizing means)
7b, 21, 22, 34 Resistance 8 Capacitor (starting capacitor)
9 Capacitor 10 AC power supply 11 Overcurrent determination device (overcurrent determination means)
12 current detector 13 relay 14 shredder control device 16 governor switch 20 control power circuit 31 resistance (means for detecting)
32 Diode (Measuring means)
33 Zener diode 35 Electrolytic capacitor (Measuring means)
41 Comparator (determination means)
42, 43 Resistance (energizing means, energizing means)
44 Diode 45 Electrolytic Capacitor (Energizing means, Energizing means)
51 Comparator (energizing means, energizing means)
Vcc DC power supply

Claims (2)

A method for preventing reverse rotation of a single-phase motor having an auxiliary winding that is a phase-separated starting type having an auxiliary winding for starting, or a capacitor starting capacitor induction type having a starting capacitor for starting,
After turning on the power, after energizing the auxiliary winding for starting (phase separation starting type) or the starting capacitor (capacitor starting capacitor induction type) for a predetermined time, an induced voltage generated in the auxiliary winding is detected, and the detected induction is detected. It is determined whether or not the voltage is lower than a predetermined voltage, and when it is determined that the induced voltage is lower than the predetermined voltage, the start-up time is equal to or longer than the time required to determine whether or not an overcurrent flows in the single-phase motor. A method for preventing reverse rotation of a single-phase motor, wherein current is supplied to the auxiliary winding (phase separation start type) or the start capacitor (capacitor start capacitor induction type). In a single-phase motor control circuit that performs drive control of a single-phase motor having an auxiliary winding that is a phase-separated starting type having an auxiliary winding for starting, or a capacitor starting capacitor induction type having a starting capacitor for starting,
After turning on the power, energizing means for energizing the auxiliary winding for start-up (phase separation start type) or the start capacitor (capacitor start capacitor induction type) for a predetermined time, and after the energizing means energizes for a predetermined time, the single phase An overcurrent determination unit that determines whether or not an overcurrent flows through the motor, a unit that detects an induced voltage generated in the auxiliary winding after the energization unit is energized for a predetermined time, and an induced voltage detected by the unit is A determination means for determining whether or not the voltage falls below a predetermined voltage; and when the determination means determines that the voltage falls below the predetermined voltage, the start auxiliary winding ( A single-phase motor control circuit comprising a means for energizing the start capacitor (capacitor start capacitor induction type).

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