JP2006333577A - Inverter device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To precisely determine a light load by eliminating troublesome setting and adjusting work by a worker when performing light-load high-speed operation. <P>SOLUTION: An operation control means 20 performs constant-speed operation at a light-load determination frequency f1 in a normal operation mode, and accelerates the speed of a motor 2 up to a high-speed operation frequency f2 when a torque current Iq detected by a load detection means 19 is not larger than a light-load determination torque current Itrq1. A data setting means 22 drives the motor 2 at the light-load determination frequency f1 in a data setting mode, and automatically sets the average value of the torque current Iq detected by the load detection means 19 as the light-load determination torque current Itrq1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an inverter device that performs light load high-speed operation for increasing the rotation speed of a motor at light load.

This type of inverter device is widely used to drive a crane or hoist hoisting motor that moves a load up and down for the purpose of improving cargo handling efficiency. Specifically, as described in the following patent document, when an operation command is input, the motor operates at a predetermined light load determination frequency, and the motor is operated based on inverter internal information such as torque and current during the operation. It is determined whether the load is light, and if it is determined that the load is light, control is performed to increase the rotation speed of the motor. If the light load state is mistakenly determined, the hoisting motor may stall, so that accurate load detection and light load determination are required.
Japanese Patent No. 3472662 JP-A-8-107699 Utility Model Registration No. 2545288 Japanese Patent Laid-Open No. 11-246182 Japanese Patent Publication No. 7-4080

  In a conventional inverter device, an operator sets a criterion for determining whether or not the load is light. The operator assumes a load state in which he / she wants to operate at high speed with no load based on the operation state in actual crane work or the like, and temporarily sets a judgment reference value (for example, a torque current reference value) corresponding to the load state to the inverter device. Set. When the provisional setting is completed, the operator actually performs a test operation and adjusts the determination reference value so that the shift to the high speed operation is as intended. However, in order to perform this adjustment work accurately, it is necessary to repeatedly perform the trial run and the adjustment of the determination reference value, which requires labor and time, resulting in deterioration of work efficiency.

  In addition, when the load suspended from the cable is only the hook, if the hoist is in contact with the floor and the cable is slackened, the hook is removed from the state where the cable is wound up when the ground is cut off, that is, when the hook is separated from the ground. The load state changes suddenly. At this time, since a spring-like load is temporarily generated and the load vibrates, it is more difficult for the operator to set the determination reference value.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an inverter device that eliminates troublesome setting and adjustment work by an operator and enables accurate light load determination when performing light load high speed operation. There is to do.

In order to achieve the above object, an inverter device according to claim 1 comprises:
In an inverter apparatus comprising a load detecting means for detecting a load of a motor to be driven, and a control means for performing a light load high speed operation for increasing the rotation speed of the motor when the load detected by the load detecting means is small.
The control means includes data setting means for setting operation reference data in which execution conditions for the light load high speed operation are defined, and operation control for controlling execution of the light load high speed operation based on the set operation reference data. Means and
The data setting means drives the motor under a predetermined condition in a data setting mode distinguished from the normal operation mode, and obtains the operation reference data based on the load detected by the load detection means in the driving state. It is characterized by setting.

  According to the inverter device of the present invention, the data setting means drives the motor under a predetermined condition in the data setting mode, and sets the operation reference data based on the load detected by the load detection means in the driving state. Thus, the operator does not need to set operation standard data relating to light load high speed operation, and the work efficiency can be improved, and more appropriate and accurate operation standard data can be obtained. In addition, since accurate operation reference data can be obtained, it is possible to accurately determine a light load.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows an electrical configuration of a hoisting device provided in the hoist crane device. In this hoisting device, the inverter motor 1 performs variable speed control of a hoisting motor 2 (for example, an induction motor). The output of the motor 2 is transmitted to the winding drum 4 via a mechanical brake device 3 and a speed reducer (not shown), and when the motor 2 rotates, the load 7 is lifted by the cable 5 to which the hook 6 is attached. It is supposed to be.

  The inverter device 1 includes a main circuit unit 8 and a control unit 9. The main circuit unit 8 rectifies an AC voltage supplied from the three-phase AC power supply 10 and outputs the rectified voltage between the power supply lines 11 and 12, a smoothing capacitor 14 connected between the power supply lines 11 and 12, and a power supply line 11 includes an inverter 15 that converts a DC voltage between 11 and 12 into an AC voltage, and current detectors 16 and 17 that detect a current flowing from the inverter 15 to the motor 2.

  Here, the converter 13 is configured by connecting a diode 13a to a three-phase bridge, and the inverter 15 connects a switching element 15a made of IGBT or the like to a three-phase bridge, and also connects a free-wheeling diode 15b to each switching element 15a in parallel. It is constituted by. A rotation speed detector 18 such as a rotary encoder is attached to the rotation shaft of the motor 2.

  The control unit 9 (corresponding to the control means) receives various signals such as an operation command signal, a frequency command signal, an automatic setting selection signal, current detectors 16 and 17 input from an operation unit (not shown, corresponding to the selection means) The gate drive signal of the inverter 15 is generated based on the phase current of the motor 2 detected by the above, the rotational speed detected by the rotational speed detector 18, and the like. The control unit 9 includes a processor capable of executing various calculations related to motor control represented by V / f constant control at high speed, and performs software processing on each calculation according to a program stored in the memory. Yes. The control unit 9 includes a timer.

  The control unit 9 shown in FIG. 1 represents each function executed by the software process in blocks. The load detection means 19 detects the load of the motor 2 and detects the torque current Iq in the present embodiment. The operation control means 20 drives the motor 2 according to the frequency command signal in the normal operation mode, and performs light load high speed operation based on the operation reference data stored in the storage means 21.

  The data setting means 22 drives the motor 2 under a predetermined condition in a data setting mode distinguished from the normal operation mode, and the operation reference data based on the load detected by the load detection means 19 in the driving state. Is set automatically. The drive circuit 23 receives the PWM-modulated gate drive signal output from the operation control means 20, performs insulation and voltage conversion, and outputs it to the inverter 15. The display means 24 (corresponding to the notification means) outputs information related to the operation of the inverter device 1 and the automatic setting of the operation reference data. The control unit 9 also generates an operation command signal for the mechanical brake device 3.

Next, the operation of the inverter device 1 will be described with reference to FIGS.
The inverter device 1 has a normal operation mode that is executed when the automatic setting selection signal is at the L level and a data setting mode that is executed when the automatic setting selection signal is at the H level. The normal operation mode is an operation mode in which the motor 2 is driven in accordance with the frequency command signal in the actual winding work, and the cable 5 is wound up or down. In this normal operation mode, the operation control means 20 performs light load high speed operation for increasing the rotation speed of the motor 2 when the load detected by the load detection means 19 is small. On the other hand, the data setting mode is a mode in which the operation reference data used by the data setting means 22 for the light load high speed operation is automatically set before the actual operation is started.

FIG. 2 is an explanatory diagram of light load high speed operation in the normal operation mode.
The operation reference data stored in the storage means 21 defines the execution conditions for light load high speed operation. Light load determination frequencies f1, f1L, detection start delay time Tw1, light load determination time T1, light load determination torque It consists of data such as current Itrq1, allowable arrival time Ta, high-speed operation frequencies f2, f2L, acceleration load determination torque current Itrq2, detection start delay time Tw2, load measurement time T2, high-speed operation load determination torque current Itrq3. Since the load state is different between the forward rotation of the motor 2 that winds up the cable 5 and the reverse rotation of the motor 2 that lowers the cable 5, individual operation reference data is provided for each. In addition, it is not individual operation reference data at the time of forward rotation and reverse rotation of the motor 2, but individual operation reference data at the time of power running and regeneration of the motor 2, and the operation reference in each state from the information inside the inverter. There are also cases where light load high speed operation is performed using data.

First, the light load high speed operation in the normal operation mode will be described with reference to FIG.
When the operation command signal for the hoisting operation becomes H level (time t1), the operation control means 20 sets the light load determination frequency f1 to the command frequency fc and accelerates the motor 2 to the light load determination frequency f1. When the motor 2 reaches the light load determination frequency f1L that is lower than the light load determination frequency f1 by the arrival detection width, the arrival signal changes to the H level (time t2). The operation control means 20 starts to input the torque current Iq from the load detection means 19 at the time when the detection start delay time Tw1 elapses from this arrival time (time t4), and until the light load determination time T1 elapses (time The average value of the torque current Iq in the period from t4 to time t5) is calculated.

  The operation control unit 20 determines whether the operation is forward rotation operation or reverse rotation operation (or power running operation or regenerative operation), and reads Itrq1 which is operation reference data of the operation state from the storage unit 21. Here, the case of winding, that is, the normal rotation operation (or power running operation) will be described. If the average value is less than or equal to the read light load determination torque current Itrq1, it is determined that the load is light, the high speed operation frequency f2 is set to the command frequency fc, and the motor 2 is accelerated to the high speed operation frequency f2. If the average value of the torque current Iq is larger than the light load determination torque current Itrq1, it is determined that the load is heavy and the operation is continued with the light load determination frequency f1.

  The operation control means 20 continues to monitor whether or not the light load state is maintained even after determining the light load. When the motor 2 reaches the high-speed operation frequency frequency f2L that is lower than the high-speed operation frequency f2 by the arrival detection width, the arrival signal changes to the H level again (time t6). The operation control means 20 continues to detect the maximum value of the torque current Iq from the acceleration start time until the detection start delay time Tw2 elapses (period from time t5 to time t8).

  When the maximum value exceeds the acceleration load determination torque current Itrq2, the light load determination frequency f1 is set to the command frequency fc, and the motor 2 is decelerated to the light load determination frequency f1. . Further, even when the allowable arrival time Ta has elapsed from the acceleration start time t5, even if the high-speed operation frequency f2L has not been reached, it is determined that the load is not light and the motor 2 is decelerated to the light load determination frequency f1.

  Furthermore, the operation control means 20 continues to monitor whether or not the light load state is maintained even during constant speed operation at the high speed operation frequency f2. That is, the operation control means 20 continues to calculate the average value of the torque current Iq even after the detection start delay time Tw2 has elapsed (after time t8). When this average value exceeds the high-speed driving load determination torque current Itrq3, it is determined that the load is not light, and the light load determination frequency f1 is set to the command frequency fc, and the motor 2 is decelerated to the light load determination frequency f1. . When the operation command signal becomes L level (time t9), the operation is decelerated and stopped. The above operation is the same even when the cable 5 is lowered. At this time, it is necessary to use the determination torque currents Itrq1, Itrq2, and Itrq3 for the reverse operation (or regenerative operation).

  FIG. 3 is an explanatory diagram of the data setting operation in the data setting mode, and FIG. 4 shows a flowchart of the data setting operation executed by the data setting means 22. Hereinafter, the data setting operation in the data setting mode will be described with reference to FIG. 3 and FIG.

  The operator sets the load state that he / she wants to operate at high speed as a light load, for example, the maximum load that allows high-speed operation, then operates the operation unit to set the automatic setting selection signal to H level, and further sets the operation command signal for hoisting operation to H The level is set (time t11 shown in FIG. 3). Thereby, it transfers to the data setting mode which sets the driving | operation reference data in winding operation. In the data setting mode, the operation is the same as the light load high speed operation in the normal operation mode, but the operation is performed up to the light load determination frequency f1 and the high speed operation frequency f2, and basically the load detection measurement based on the internal information of the inverter. Is different from the normal operation mode in that operation reference data used in light load high speed operation is set.

  The data setting means 22 rewrites the mode flag to the data setting mode in step S1. Thereby, the display unit 24 displays information indicating that the operation reference data is being set during the data setting mode. Subsequently, in step S2, the light load determination frequency f1 is set to the command frequency fc, and the frequency f is determined until the rotational frequency f of the motor 2 reaches the light load determination frequency f1L lower than the light load determination frequency f1 by the arrival detection width. Step S3 is repeated.

  When the frequency f reaches the light load determination frequency f1L (time t12), the data setting means 22 proceeds to step S4 and clears the timer value T to 0, and the timer until the timer value T reaches the detection start delay time Tw1. The determination step S5 for the value T is repeated. This detection start delay time Tw1 is the time required for the torque current Iq to stabilize after reaching the light load determination frequency f1L, and is set by the data setting means 22. When the timer value T reaches the detection start delay time Tw1 (time t14), the average value of the torque current Iq detected by the load detection means 19 is calculated during the period from the time t15 when the light load determination time T1 elapses.

  Specifically, in step S6, the timer value T and the light load determination torque current Itrq1 are cleared to 0, and the torque current Iq is changed to the light load determination torque current Itrq1 until the timer value T becomes equal to or longer than the light load determination time T1. Continue to add to. If it is determined in step S7 that the timer value T has reached or exceeded the light load determination time T1, the process proceeds to step S9, and the light load determination torque current as an average value is obtained by dividing the added light load determination torque current Itrq1 by the number N of additions. Find Itrq1.

  In step S10, it is determined whether or not the obtained light load determination torque current Itrq1 is in a normal range. For example, when the light load determination torque current Itrq1 is larger than the maximum torque current that can flow at the high-speed operation frequency f2, the high-speed operation cannot be performed and the routine proceeds to a predetermined abnormality process. In this abnormality process, the display means 24 displays information indicating that data setting cannot be performed, and the operation control means 20 stops the operation reference data setting operation.

  If the data setting means 22 determines in step S10 that the light load determination torque current Itrq1 is within the normal range (YES), the data setting means 22 proceeds to step S11, sets the high speed operation frequency f2 to the command frequency fc, and further proceeds to step S12. Then, the acceleration judgment load current Itrq2 is cleared to zero. Thereafter, until the rotation frequency f of the motor 2 reaches the high-speed operation frequency f2L lower than the high-speed operation frequency f2 by the arrival detection width (period from time t15 to time t16) and the detection start delay time Tw2 from this arrival time. Until the time elapses (period from time t16 to time t18), the maximum value of the torque current Iq is continuously detected. The detection start delay time Tw2 is the time required for the torque current Iq to stabilize after reaching the high speed operation frequency f2L, and is set by the data setting means 22.

  Specifically, until it is determined in step S13 that the frequency f has reached the high-speed operation frequency f2L (YES), the maximum value of the torque current Iq is detected in step S14, and this is determined as the acceleration load determination torque current Itrq2. Set to. Further, the timer value T is cleared to 0 in step S15, and the maximum value of the torque current Iq is set in step S17 until it is determined in step S16 that the timer value T is equal to or longer than the detection start delay time Tw2 (YES). It is detected and set to the load judgment torque current Itrq2 during acceleration.

  Thereafter, the process proceeds to step S18, and it is determined whether or not the acceleration load determination torque current Itrq2 is within a normal range. This determination process is the same as the determination process in step S10, and in the case of abnormality, the above-described abnormality process is executed. The data setting means 22 measures the time Tr from the start of acceleration to the high speed operation frequency f2 until the high speed operation frequency f2L is reached, and sets the allowable arrival time Ta based on this measurement time Tr.

  Subsequently, the data setting means 22 calculates the average value of the torque current Iq at the high speed operation frequency f2 until the load measurement time T2 elapses (period from time t18 to time t19), and calculates it as the high speed operation load. The determination torque current Itrq3 is used. Specifically, the timer value T and the high-speed driving load determination torque current Itrq3 are cleared to 0 in step S19, and the torque current Iq is changed to the high-speed driving load determination torque current until the timer value T becomes equal to or longer than the load measurement time T2. Continue to add to Itrq3. If it is determined in step S20 that the timer value T is equal to or greater than the load measurement time T2 (YES), the process proceeds to step S22, and the high-speed operation load determination torque current Itrq3 is divided by the number N of additions to obtain a high-speed average value. The operating load determination torque current Itrq3 is obtained.

  And it transfers to step S23 and it is judged whether the high-speed driving | running | working load determination torque electric current Itrq3 is a normal range. This determination process is also the same as the determination process in step S10. In the case of abnormality, the above-described abnormality process is executed. When each of the above processes ends normally, the data setting means 22 increases the light load determination torque current Itrq1, the acceleration load determination torque current Itrq2, the high speed operation load determination torque current Itrq3, and the arrival allowable time Ta in step S24. Is written in the storage means 21 as the operation reference data. Note that these determination torque currents Itrq1, Itrq2, Itrq3 and the allowable arrival time Ta are not the measured current value and time but are added with a predetermined margin.

  Here, the data setting in the winding operation has been described, but the same applies to the winding operation. Further, the data setting means 22 determines whether the state is a power running operation or a regenerative operation, and sets operation reference data corresponding to the operation state. Furthermore, it is also possible to set the operation reference data at the time of forward / reverse operation by continuously performing the forward rotation operation (winding operation) and the reverse rotation operation (lowering operation).

  As described above, the inverter device 1 of the present embodiment is used for a hoisting device of a hoist crane device, and operates at a high rotational speed when the motor 2 is in a light load state in the normal operation mode. Work can be made more efficient. The operation reference data such as determination torque currents Itrq1, Itrq2, and Itrq3 used for the determination of the light load state is automatically set by the data setting means 22 in the data setting mode. It is freed from troublesome setting work (adjustment work) of the operation standard data, and the work time can be shortened. Further, unlike the manual adjustment, the accurate torque current Iq can be detected even when a ground cut occurs, so that it is possible to set accurate operation reference data and perform a highly accurate light load determination.

  The operation control means 20 performs light load determination at a light load determination frequency f1 capable of generating the maximum torque (rated torque) in motor control represented by V / f constant control. The operation is continued with the frequency f1, and when the load is light, the operation is performed at a higher high-speed operation frequency f2. Therefore, the hoisting operation can be performed at an appropriate rotational speed corresponding to the hoisting load 7 regardless of the magnitude of the load.

  The operation control means 20 monitors whether the light load state is maintained not only during the light load determination frequency f1 but also during acceleration to the high speed operation frequency f2 when the light load is determined and during the high speed operation frequency f2. ing. In order to accurately perform the light load determination, the operation reference data includes the light load determination torque current Itrq1 that is the light load determination reference at the light load determination frequency f1 and the acceleration load that is the light load determination reference during acceleration. It has a determination torque current Itrq2 and a high-speed operation load determination torque current Itrq3 which is a light load determination reference at the high-speed operation frequency f2. Even when the cable 5 is wound up from the slack state by such constant monitoring, it is possible to immediately determine that the load 7 is a heavy load and return to the light load determination frequency f1 when the load 7 leaves the ground, thereby preventing the motor 2 from stalling. can do.

  The light load determination at the light load determination frequency f1 and the high speed operation frequency f2 is performed after the detection start delay times Tw1 and Tw2 have elapsed since reaching the light load determination frequency f1L and the high speed operation frequency f2L, respectively. The light load determination can be performed while avoiding the transient state of the torque current Iq when shifting to the constant speed operation. The light load determination at the light load determination frequency f1 and the high speed operation frequency f2 is performed by comparing the average value of the torque current Iq with the light load determination torque current Itrq1 and the high speed operation load determination torque current Itrq3, respectively. Even if a general disturbance occurs, it is difficult to make a misjudgment.

  If the motor 2 has not reached the high-speed operation frequency f2 when the allowable arrival time Ta has elapsed from the start of acceleration to the high-speed operation frequency f2, the operation control means 20 stops the acceleration to the high-speed operation frequency f2 and lightly Decelerate to load judgment frequency f1. This control can also detect the heavy load state and prevent the motor 2 from stalling.

  The data setting operation in the data setting mode needs to be performed in a light load state capable of high speed operation. On the other hand, if the light load determination torque current Itrq1 obtained in the data setting mode exceeds the upper limit value of the torque current Iq that can flow at the high speed operation frequency f2, for example, the light load determination torque current Itrq1 is set. Not performed. As a result, it is possible to prevent erroneous setting of the operation reference data under a condition that is not in a light load state. The same applies to the acceleration load determination torque current Itrq2 and the high speed driving load determination torque current Itrq3. In this case, since information indicating that the data setting cannot be performed is displayed on the display unit 24, the operator can easily recognize that the data setting has not been completed normally.

  The operation reference data is set by the operator operating the operation unit to select the data setting mode and turning on the operation command. In this selection, it is possible to specify whether the data setting is to be performed in normal operation, reverse operation, continuous operation of normal rotation or reverse operation, so set operation reference data as necessary according to the crane work. Can do. Further, during the data setting mode, the display means 24 displays that the operation reference data is being set, so that erroneous operation can be prevented.

The present invention is not limited to the embodiment described above and shown in the drawings. For example, the present invention can be modified or expanded as follows.
The data setting means 22 may be configured to set the high speed operation frequency f2 according to the light load determination torque current Itrq1 obtained during the operation continuation period at the light load determination frequency f1 in the data setting mode. In this case, for example, as the light load determination torque current Itrq1 is larger, the high speed operation frequency f2 is preferably set lower.

The operation control means 20 and the data setting means 22 are configured to perform operation control and automatic setting of operation reference data using values obtained by processing the torque current Iq detected by the load detection means 19 with a first-order lag filter, respectively. Also good.
The load of the motor 2 is detected by the torque current Iq, but instead of this, it corresponds to the load information detection amount, the internal information of the inverter such as the input power and output power of the inverter device 1, or a load that can be calculated from them or can be substituted You may comprise so that it may detect with an appropriate quantity.

Electrical configuration diagram of a hoisting apparatus showing an embodiment of the present invention Illustration of light load high speed operation in normal operation mode Illustration of data setting operation in data setting mode Flow chart of data setting operation executed by data setting means

Explanation of symbols

In the drawings, 1 is an inverter device, 2 is a motor, 9 is a control unit (control means), 19 is load detection means, 20 is operation control means, 22 is data setting means, and 24 is display means (notification means).

Claims (25)

In an inverter apparatus comprising a load detecting means for detecting a load of a motor to be driven, and a control means for performing a light load high speed operation for increasing the rotation speed of the motor when the load detected by the load detecting means is small.
The control means includes data setting means for setting operation reference data in which execution conditions for the light load high speed operation are defined, and operation control for controlling execution of the light load high speed operation based on the set operation reference data. Means and
The data setting means drives the motor under a predetermined condition in a data setting mode distinguished from the normal operation mode, and obtains the operation reference data based on the load detected by the load detection means in the driving state. An inverter device characterized by setting. The operation reference data includes at least light load determination frequency, light load determination time, and light load determination torque data,
In the normal operation mode, the operation control means accelerates the motor to the light load determination frequency after starting operation, and after reaching the light load determination frequency, at least the light load determination time at the light load determination frequency. The operation is continued, and it is determined whether or not to further increase the rotation speed of the motor based on the load detected by the load detection means and the light load determination torque during the operation continuation period. 1. The inverter device according to 1. The operation reference data further includes data of a high-speed operation frequency and acceleration load determination torque,
In the normal operation mode, when the operation control means determines that the rotation speed of the motor is further increased by a light load, the operation control means accelerates the motor toward the high-speed operation frequency, and during this acceleration period, the load detection means The inverter device according to claim 2, wherein it is determined whether or not to continue the acceleration based on the detected load and the acceleration determination torque during acceleration. The operation reference data further includes data on allowable arrival time,
The operation control means stops the acceleration to the high-speed operation frequency when the motor has not reached the high-speed operation frequency at the time when the allowable time has elapsed from the start of acceleration to the high-speed operation frequency. The inverter device according to claim 3. The operation reference data further includes high-speed operation load determination torque data,
The operation control means determines whether to continue the operation at the high speed operation frequency based on the load detected by the load detection means and the high speed operation load determination torque during the operation at the high speed operation frequency. The inverter device according to claim 3. The operation reference data includes at least light load determination frequency, light load determination time, and light load determination torque data,
In the data setting mode, the data setting means accelerates the motor to the light load determination frequency after starting operation, and after reaching the light load determination frequency, at least the light load determination time at the light load determination frequency. 2. The inverter device according to claim 1, wherein the operation is continued and the light load determination torque is set based on the load detected by the load detection means during the operation continuation period. The operation reference data further includes data of a high-speed operation frequency and acceleration load determination torque,
In the data setting mode, the data setting means accelerates the motor toward the high-speed operation frequency, and sets the acceleration load determination torque based on the load detected by the load detection means during the acceleration period. The inverter device according to claim 6. The operation reference data further includes data on allowable arrival time,
8. The inverter device according to claim 7, wherein the data setting means sets the allowable arrival time based on a time from the start of acceleration to the high speed operation frequency until the high speed operation frequency is reached. The operation reference data further includes high-speed operation load determination torque data,
8. The inverter device according to claim 7, wherein the data setting means sets the high-speed operation load determination torque based on a load detected by the load detection means during operation at the high-speed operation frequency.   7. The inverter device according to claim 6, wherein the data setting means does not set the light load determination torque when the light load determination torque obtained in the data setting mode exceeds a predetermined upper limit value. A notification means for outputting information;
11. The inverter device according to claim 10, wherein the data setting means outputs abnormality information by the notification means when the light load determination torque is not set.   8. The inverter device according to claim 7, wherein the data setting means sets the high-speed operation frequency based on a load detected by the load detection means during an operation continuation period at the light load determination frequency. The operation reference data includes a detection start delay time,
6. The inverter according to claim 2, wherein the operation control unit starts determining the magnitude of the load after the detection start delay time has elapsed after reaching the light load determination frequency or the high speed operation frequency. apparatus. The operation reference data includes a detection start delay time,
The data setting means sets the detection start delay time based on a load detected by the load detection means after reaching the light load determination frequency or the high speed operation frequency. The described inverter device.   The data setting means sets, as the detection start delay time, a time from when the light load determination frequency or the high-speed operation frequency is reached until the load detected by the load detection means is stabilized. The inverter device according to claim 14.   16. The inverter device according to claim 1, wherein the operation reference data is data in which the data at the time of forward rotation and the data at the time of reverse rotation of the motor are separate data.   The data setting means determines whether the forward operation or the reverse operation is performed when setting the operation reference data, and sets operation reference data corresponding to the operation direction. The described inverter device.   17. The data setting means, when setting the operation reference data, continuously performs forward rotation operation and reverse rotation operation, and sets operation reference data corresponding to each operation direction. Inverter device.   The inverter device according to any one of claims 1 to 18, wherein the operation reference data is data in which powering data and regeneration data of the motor are separate.   The said data setting means judges whether it is a power running operation or a regenerative operation when setting the said driving | operation reference data, and sets the driving | operation reference data corresponding to the driving | running state. Inverter device. A notification means for outputting information;
The said data setting means outputs the information which shows that the setting operation | movement of the said driving | operation reference data is being performed during the period of the said data setting mode by the said alerting | reporting means. Inverter device. Comprising a selection means for selecting whether or not to perform the setting operation of the operation reference data;
The said data setting means starts the setting operation | movement of the said driving | operation reference data according to driving | operation command, when performing setting operation | movement of the said driving | operation reference data is selected by the said selection means. The inverter apparatus in any one of 21.   23. The operation control unit and the data setting unit respectively perform operation control and setting of the operation reference data using an average value of the load detected by the load detection unit. An inverter device according to any one of the above.   23. The operation control unit and the data setting unit respectively perform operation control and setting of the operation reference data using a maximum load value detected by the load detection unit. An inverter device according to any one of the above. The operation control means and the data setting means respectively perform operation control and setting of the operation reference data using values obtained by processing a load detected by the load detection means with a first-order lag filter. The inverter device according to any one of 1 to 24.

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