JP2001072387A - Hoisting and lowering device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the heating of a discharge resistor without using any electric part such as thermometal cut-out or relay by turning OFF a discharge resistor switching element to stop the current-carrying to the discharge resistor when the current-carrying time rate of an inverter drive circuit exceeds an allowable current-carrying time rate. SOLUTION: The ratio of lowering operation time to the whole time including hoisting operation time, stopping time and lowering operation time is set to a current-carrying time rate, and the allowable maximum value of the current- carrying time is set as an allowable current-carrying time rate. A central control part 9c is constituted so as to output ON signal when the current-carrying time rate is under the allowable current-carrying time rate, and outputs OFF signal when the current-carrying time rate exceeds it. When the ratio of the lowering operation time increases, and the current-carrying time rate exceeds the allowable current-carrying time rate, the central control part 9c outputs the OFF signal to an AND circuit 9f, whereby an L-level signal is outputted from the AND circuit 9f, so that a discharge resistor switching element 4 is OFF to stop the current-carrying to a discharge resistor 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an operation control of regenerative braking in which electric energy generated in a motor for driving up and down driven by an inverter drive circuit is consumed by a discharge resistor when the motor is lowered.

[0002]

2. Description of the Related Art A conventional hoist will be described with reference to FIG.

The rectifier circuit 1 has a diode module 1a. The input side of the rectifier circuit 1 is a three-phase AC power supply, and the output side is a smoothing capacitor 2 for smoothing the rectification of the pulsating flow.
Is provided. On the AC power supply side, a switching contact 7 for a relay 13 is provided. The discharge resistor 3 is provided on the output side of the rectifier circuit 1 via the discharge resistor switching element 4.

[0004] The motor 5 for winding up and down is connected to the output side of the rectifier circuit 1 via an inverter drive circuit 6. The inverter drive circuit 6 has a diode 6a and a drive switching element. An inverter control circuit 12 is connected to the inverter drive circuit 6, and a manual operation device 8 is connected to the inverter control circuit 12.

A thermoswitch 10 provided near the discharge resistor 3 is connected to the relay 13 in series. A voltage detector 11 that detects a voltage on the output side of the rectifier circuit 1 controls ON / OFF of the discharge resistance switching element 4.

[0006] The forward braking is performed by discharging electric energy generated during the lowering operation of the motor 5 by the discharge resistor 3.

The motor 5 for winding up and down is not operated continuously, but is repeatedly stopped and operated. If the usage rate (operating rate) per unit time in the stop and operation is 40% ED, the usage rate of the lowering is halved (20% ED).

When the use rate of the lowering becomes 20% ED or more, the energizing time per unit time to the discharge resistor 3 becomes longer. There is a risk that the temperature of the discharge resistor 3 will rise to a temperature higher than the specified value. The temperature of the discharge resistor 3 is detected by the thermostat 10 so that the rising temperature does not exceed the specified value, and the power supply side is turned off by the switching contact 7 through the relay 13 before the temperature exceeds the specified value.

The electric components of the thermoswitch 3 and the relay 13 have been a factor of increasing the component cost. Further, the thermoswitch 3 is required to have an operation accuracy in preventing the discharge resistor 3 from being heated. Since the thermoswitch 3 is used in a situation that is often affected by the temperature, maintenance and inspection must be frequently performed, which is troublesome.

[0010]

SUMMARY OF THE INVENTION It is an object of the present invention to address the above-mentioned drawbacks and to prevent the heating of the discharge resistor without using electric components such as thermoswitches and relays.

[0011]

SUMMARY OF THE INVENTION The present invention relates to a rectifier circuit for converting an alternating current into a direct current, a smoothing capacitor provided on the output side of the rectifier circuit, a discharge resistor for regenerative braking, an inverter drive circuit, and an inverter drive circuit. In a hoisting and lowering device comprising a motor for winding up and down driven by energization, a discharge resistance switching element for turning on and off the energization of the discharge resistor, and an inverter control circuit for controlling energization of the inverter drive circuit, The ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time, and the lowering operation time is referred to as an energization time ratio d.
The maximum value allowed in the above is defined as an allowable energization time ratio dr, and when the energization time ratio d exceeds the allowable energization time ratio dr, the switching element for the discharge resistor is turned off to stop energization of the discharge resistor. It is.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIG.

First, a schematic circuit diagram of a hoist and lowering machine called a hoist will be described. 2 denote the same parts.

The rectifier circuit 1 has an input side connected to a three-phase power supply. The output side of the rectifier circuit 1 is provided with a smoothing capacitor 2 for smoothing the rectification of the pulsating flow. Condenser 2
Use two of 5600 μF. Condenser 2
Are connected to the P pole and the N pole which are DC electrodes. The N pole side is on the ground side. The inverter drive circuit 6 connected to the P pole and the N pole has a drive switching element 6c and a flywheel diode 6a. The electric motor 5 for winding up and down is connected to the output side of the inverter drive circuit 6. Electric motor 5
Uses a three-phase induction motor. The discharge resistor 3 is connected to the P-pole and the N-pole via the discharge-resistance switching element 4.
The switching element 4 for the discharge resistance uses a transistor. The discharge resistor 3 has a resistance value of 4 to 50Ω and a capacity of 3000.
の も の 500 W is used. The current detector 7 detects a load current of the electric motor 5.

The main control unit 9 includes a central control unit 9c, an inverter control circuit 9a, a current / voltage converter 9b for converting a load current detected by the current detector 7, a display unit 9d, a voltage detection circuit 9e, and an AND circuit 9f. Having.

The central control unit 9c is formed of a microprocessor or the like, and controls the operation device 8 to wind up and down,
Alternatively, the operation of the electric motor 5 is controlled in response to a stop instruction or the like.

The inverter control circuit 9a includes a central control unit 9
In response to the control instruction relating to the operation c, the inverter drive circuit 6 is presented with voltage frequency information, hoisting information, lowering information, stop information, etc. relating to the operating speed.

The inverter drive circuit 6 forms an alternating current having a frequency corresponding to the operation speed specified by the operation device 8 and supplies the alternating current to the motor 5.

The motor 5 is operated to hoist and lower at a speed corresponding to the AC frequency supplied from the inverter drive circuit 6. In the lowering of this operation, the electric motor 5 has a power generating action due to the weight of the suspension load. The generated electricity flows to the output side of the rectifier circuit 1 via the flywheel diode 6a of the inverter drive circuit 6. The output side of the rectifier circuit 1 is charged to the capacitor 2 as the voltage rises due to the flow of generated electricity. When the voltage of the capacitor 2 rises, the electric charge stored in the capacitor 2 flows to the discharge resistor 3 to discharge.

The voltage of the three-phase AC power supply is 220V. The DC voltage of the capacitor 2 is used in a range of 340V to 400V. The voltage applied to the discharge resistor 3 is 360 V
Since the voltage of the capacitor 2 is 400 V
V will not be exceeded.

In the lowering operation, when the voltage between the (P-pole and N-pole) rises as the charging of the capacitor 2 progresses, the voltage detection circuit 9e outputs an ON signal for energizing the discharge resistor 3 to A.
Output to the ND circuit 9f. The AND circuit 9f outputs an ON signal for prompting the discharge resistor 3 to be energized from the central control unit 9c, and when the two ON signals overlap, an H level signal for turning on the transistor of the discharge resistor switching element 4 is inputted. Is output. The discharge switching element 4 is turned on by this H level signal, and the electric charge charged in the capacitor 2 flows to the discharge resistor 3 and is consumed. The discharge resistor 3 consumes the electric energy charged in the capacitor 2 and the electric energy generated by the electric motor 5. The regenerative braking of the electric motor 5 is performed by the consumption of the electric energy.

The central control section 9c outputs the above-mentioned ON signal in the following case.

First, the ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time and the lowering operation time is defined as the energization time rate d, and the maximum value permitted by the energization time rate d is the allowable energization time. It is assumed that the rate is dr. And
When the energization time ratio d is lower than the allowable energization ratio dr, O
The central control unit 9c is configured to output an N signal and output an OFF signal when the N signal is exceeded.

As described above, when the ratio of the duration of the winding operation increases and the energization time rate d exceeds the allowable energization time rate dr, the central control section 9c outputs an OFF signal to the AND circuit 9f. For this reason, the voltage between the (P-pole and N-pole) is high, and the voltage detection circuit 9e sends an O signal to the AND circuit 9f.
Since the AND circuit 9f outputs an L level signal even when the N signal is output, the discharge switching element 4 is turned off, and the conduction of the discharge resistor 3 is stopped. When the current supply to the discharge resistor 3 is stopped during the lowering operation, the central control unit 9c issues an instruction to stop the electric motor 5 to the inverter drive circuit 6 via the inverter control circuit 9a. By doing so, it is possible to prevent the discharge resistance 3 from being heated and damaged due to an excessively large proportion of the winding operation time.

The set value of the allowable energization time ratio dr is 2
0% is appropriate. If the lowering operation exceeding this is continued, the electric motor 5 is forcibly stopped and displayed on the display unit 9d. The set value of 20% depends on the weight of the suspended load. To realize this, the load current of the electric motor 5 is detected by the current detector 7, the detected value is taken into the central control unit 9c, and the set value of the allowable energizing time ratio dr is corrected according to the capacity of the load current. To do.

The energization time ratio d will be further described with reference to FIG. FIG. 3 shows an example of an operation pattern in which winding, stopping, and winding are completed. The total time including the winding time t1, the stopping time, and the lowering time t2 is T.
In the hoisting and lowering device, the reciprocating operation of hoisting and lowering is performed at substantially the same speed, so that the hoisting time t1 and the lowering time t2 are substantially the same. For this reason, the duty ratio d is
It is half of (t1 + t2 / T). Allowable duty ratio dr (2
0%) is the average of various driving patterns.

The energization time ratio will be further described with reference to FIG.

Ia ² · d indicates the calorific value of the discharge resistance under the rated load. Ib ² · d indicates a calorific value of discharge resistance due to a high load. Ic ² · d indicates a calorific value of discharge resistance due to a low load.

The allowable temperature value of the discharge resistance temperature with respect to the allowable energization time ratio dr at the rated load is Hr. When the energization time ratio with respect to the allowable temperature value Hr is viewed at a high load, the allowable energization time ratio (dr) ′ becomes a value smaller than dr. On the other hand, when the load is low, the allowable energization time ratio (d
r) "is greater than dr. That is, the allowable energization time ratio changes depending on the size of the load. Therefore, as described above, the set value of the allowable energization time ratio dr must be corrected according to the load current capacity. It doesn't.

FIG. 5 shows the temperature drop of the discharge resistor. As described above, during the regenerative braking, when the discharge switching element 4 is turned off and the energization of the discharge resistor 3 is stopped by the instruction of the central control unit 9c, the temperature decreases with the passage of time. When the predetermined waiting time tw has elapsed and the temperature has dropped to the predetermined temperature, the discharge switching element 4 is turned on by the instruction of the central control unit 9c, and regenerative braking is restarted. Thus, regenerative braking is performed without the discharge resistor 2 being damaged by heating.

FIG. 6 is a flowchart for preventing the discharge resistor 2 from being heated. At the start, the integration time measurement starts (step 601). It is checked in step 602 whether or not the operation is the lowering operation. If the operation is the lowering operation, measurement of the lowering time is started in step 603.
The energization time rate d is measured in step 604, and if this energization time rate d exceeds the allowable energization time rate dr, step 6
When it is determined in step 05, the energization of the discharge resistor 2 is stopped, and the operation of the electric motor 5 is stopped in step 606. Then, a message to that effect is displayed on the display unit 9d in step 607, and it is checked in step 608 whether the time is within the waiting time of the stop.

FIG. 7 shows another flowchart for preventing the discharge resistor 2 from being heated. The difference from the flowchart of FIG. 6 is that the load current value is taken into account.

At the start, integrated time measurement starts (step 601). It is checked in step 602 whether or not the operation is the lowering operation. If the operation is the lowering operation, measurement of the lowering time is started in step 603. The energization time ratio d is measured in step 604, and the winding current value I (current flowing through the discharge resistor), which is the load current value, is measured in step 701. After calculating the discharge resistance calorific value (I ² · d) in step 703 based on the winding current value I (current flowing through the discharge resistor) and the conduction time rate d, the allowable discharge resistance calorific value (Ir ² · dr) and the discharge resistance The calorific value (I ² · d) is compared in step 703. If the calorific value (I ² · d) exceeds the discharge resistance calorific value (I ² · d), the power supply to the discharge resistor 2 is stopped and the operation of the electric motor 5 is stopped in step 606. Then, a message to that effect is displayed on the display unit 9d in step 607, and it is checked in step 608 whether the time is within the waiting time of the stop.

In FIG. 6, whether or not the current supply to the discharge resistor is stopped is determined based on the current supply time ratio. On the other hand, the one shown in FIG. 7 determines whether or not the energization of the electric resistance is stopped based on the energization time ratio and the current value of the discharge resistance. It is possible to provide a selection means for arbitrarily selecting according to the weight of the suspended load, the contents of lifting work, and the like.

[0035]

As described above, the present invention provides a rectifier circuit for converting an alternating current to a direct current, a smoothing capacitor provided on the output side of the rectifier circuit, a discharge resistor and an inverter drive circuit for regenerative braking, and an inverter drive circuit. A motor for winding up and down driven by energization, a discharge resistance switching element for turning on and off the discharge resistor, and an inverter control circuit for controlling the energization of the inverter drive circuit. The ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time and the lowering operation time is defined as the energization time ratio d, and the maximum value allowed by the energization time ratio d is the allowable energization time ratio dr. When the energization time rate d exceeds the allowable energization time rate dr, the switching element for discharge resistance is turned off to stop energization of the discharge resistance. In winding up and down up apparatus characterized.

According to this, when the energizing time rate d exceeds the allowable energizing time rate dr, the discharge resistance is stopped and the heating of the discharge resistance is prevented in a soft manner.
Electric components such as relays become unnecessary. In addition, troublesome maintenance for inspecting electrical parts such as thermoswitches and relays is not required.

[Brief description of the drawings]

FIG. 1 is a circuit diagram of a hoisting and lowering device called an inverter-driven hoist according to an embodiment of the present invention.

FIG. 2 is a circuit diagram of a hoisting and lowering device referred to as an inverter-driven hoist according to a conventional example.

FIG. 3 is a view showing an operation pattern of hoisting, stopping, and winding down according to an embodiment of the present invention.

FIG. 4 is a diagram showing a discharge resistance heating value due to various loads according to the embodiment of the present invention.

FIG. 5 is a diagram showing a cooling temperature drop of a discharge resistor according to an embodiment of the present invention.

FIG. 6 relates to one embodiment of the present invention, and is a view showing a process for preventing the discharge resistance from being heated based on the duty factor in the lowering operation.

FIG. 7 relates to one embodiment of the present invention, and is a diagram illustrating a process of preventing heating of the discharge resistor based on the calorific value of the discharge resistor in the lowering operation.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Rectifier circuit, 2 ... Capacitor, 3 ... Discharge resistance, 4 ... Discharge resistance switching element, 5 ... Electric motor, 6 ... Inverter drive circuit, 7 ... Current detector, 8 ... Operation device, 9 ... Main control unit, 9a ... Inverter control circuit, 9b: current / voltage conversion section, 9c: central control section, 9d: display section, 9e: voltage detection circuit, 9f: AND circuit.

Claims (6)

[Claims] 1. A rectifier circuit for converting an alternating current into a direct current, a smoothing capacitor provided on the output side of the rectifier circuit, a discharge resistor for regenerative braking and an inverter drive circuit, and a winding up and down driven by energization of the inverter drive circuit. Motor, a discharge resistance switching element for turning on and off the discharge resistor, and an inverter control circuit for controlling the power supply to the inverter drive circuit, a hoisting operation time, a stop time and The ratio of the unwinding operation time occupied in the entire time including the unwinding operation time is defined as the energization time rate d, and the maximum value permitted by the energization time rate d is defined as the allowable energization time rate dr. When the time rate dr is exceeded,
A hoisting and lowering device, characterized in that the discharge resistance switching element is turned off to stop energization of the discharge resistance. 2. The hoisting and lowering device according to claim 1, wherein an instruction to stop energization of the inverter drive circuit is issued in accordance with turning off of the discharge resistance switching element. 3. A rectifier circuit for converting an alternating current to a direct current, a smoothing capacitor provided on the output side of the rectifier circuit, a discharge resistor for regenerative braking and an inverter drive circuit, and a winding up and down driven by the current supplied to the inverter drive circuit. A motor, a switching element for the discharge resistor for turning on and off the current of the discharge resistor, an inverter control circuit for controlling the current for the inverter drive circuit, and a central control formed by a microprocessor or the like for controlling the overall operation. And a hoisting / lowering device comprising an operating device for issuing a hoisting / lowering operation instruction signal to the central control unit. The hoisting / lowering device detects an output voltage of the rectifier circuit, and the detected voltage exceeds a predetermined value. And a voltage detector for outputting an ON signal for energizing the discharge resistor, and a discharge resistor for performing ON / OFF control of the discharge resistance switching element. A control unit for the switching element, wherein the control unit for the discharge resistance switching element turns on the switching element for the discharge resistance when the ON signal of the voltage detector for energizing and the ON signal of the central control unit for energizing overlap. In addition, when the ON signals do not overlap, the switching element for the discharge resistor is turned off, and the central control unit determines the ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time, and the lowering operation time ( When the energization time rate d exceeds the allowable energization time rate dr in relation to the energization time rate d) and the maximum value (allowable energization time rate dr) permitted by the energization time rate d, energization is performed from an ON signal that prompts energization. A hoisting / lowering device characterized in that the output is changed to an OFF signal for stopping the operation. 4. A rectifier circuit for converting an alternating current into a direct current, a smoothing capacitor provided on an output side of the rectifier circuit, a discharge resistor for regenerative braking and an inverter drive circuit, and a winding up and down driven by the current supplied to the inverter drive circuit. Motor, a discharge resistance switching element for turning on and off the discharge resistor, and an inverter control circuit for controlling the power supply to the inverter drive circuit, a hoisting operation time, a stop time and The ratio of the lowering operation time occupied in the entire time including the lowering operation time is defined as the energization time ratio d, the maximum value allowed by the energization time ratio d is defined as the allowable energization time ratio dr, and the current value flowing through the discharge resistance The discharge resistance heating value (I ² · d) is determined from I and the energization time rate d, and the allowable discharge resistance heating value (Ir ² · dr) at which the discharge resistor is allowed to generate heat is defined. , By comparing the discharge resistor heating value (I ² · d) and the allowable discharge resistor heating value (Ir ² · dr), the discharge resistor heating value (I ² ·
When d) exceeds the allowable discharge resistance calorific value (Ir ² · dr), the discharge resistance switching element is turned off to stop energizing the discharge resistance. 5. A rectifier circuit for converting an alternating current into a direct current, a smoothing capacitor provided on an output side of the rectifier circuit, a discharge resistor for regenerative braking and an inverter drive circuit, and a winding up and down driven by the current supplied to the inverter drive circuit. A motor, a discharge resistance switching element for turning on and off the discharge resistor, and an inverter control circuit for controlling the power supply to the inverter drive circuit, the hoisting and lowering device, comprising the following two courses, A hoisting and lowering device characterized by being selected by a selection means. (A) Course The ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time and the lowering operation time is defined as the energization time rate d, and the maximum value permitted by the energization time rate d is the allowable energization. The discharge rate calorific value (I ² · d) is determined from the current value I flowing through the discharge resistor and the energizing time rate d, and the allowable discharge resistance calorific value (Ir ² · dr) at which heat generation of the discharge resistor is permitted. define, by comparing discharge resistor heating value and (I ² · d) allowable discharge resistor heating value (Ir ² · dr), the discharge resistor heating value (I ² ·
When d) exceeds the allowable discharge resistance calorific value (Ir ² · dr), the discharge resistance switching element is turned off to stop energizing the discharge resistance. (B) Course The ratio of the lowering operation time occupied in the entire time including the hoisting operation time, the stop time, and the lowering operation time is defined as the energization time rate d, and the maximum value allowed by the energization time rate d is the allowable energization. When the energization time rate d exceeds the allowable energization time rate dr,
The discharge resistance switching element is turned off to stop the supply of the discharge resistance. 6. The display device according to claim 1, further comprising a display unit for displaying when the discharge resistance switching element is turned off to stop energizing the discharge resistance. And hoisting and lowering device.