DE112017008143T5 - Control circuit for switching element, power conversion device, elevator device and method for driving the switching element - Google Patents

Abstract

The present invention provides a driving circuit for a switching element, including: a determination power supply unit configured to apply a voltage having a set voltage value to an input terminal of the connected switching element with an unknown driving type, to thereby turn on the switching element; a voltage measurement determination unit configured to measure a voltage value at the input terminal of the switching element in an ON state, thereby determining the switching element as a voltage-driven type when the measured voltage value is equal to or larger than a reference voltage value and as a current-driven type if the measured voltage value is less than the reference voltage value; a drive voltage generation unit configured to apply a drive voltage, which is a voltage adapted to a determination result in the voltage measurement determination unit, to the input terminal of the switching element; and a changeover switch configured to switch the determination power supply unit and the voltage measurement determination unit interchangeably with the drive voltage generation unit, to thereby connect to the input terminal of the switching element.

Description

Technical part

The present invention relates to a control circuit for a switching element for use in a power conversion device configured to control a lifting machine of an elevator or the like, and in particular to a control control that takes into account the type of the switching element. The present invention further relates to a power conversion device that includes the drive circuit for a switching element, an elevator device that includes the power conversion device, and a method for driving a switching element.

State of the art

A drive circuit for a switching element is used in a power conversion device that includes an inverter and is configured to drive an elevator machine. The driving circuit for a switching element of the corresponding type is configured to apply a negative voltage to an input terminal of the switching element in an off state to perform a fast OFF operation (see e.g. Patent Literature 1). The heat generated by the switching element itself can be reduced by the rapid OFF operation.

Citation list

Patent literature

[PTL 1] JP H06-13869 A (from paragraph [0017], 4th and 5 )

Summary of the invention

Technical problem

However, the prior art has the following problems.

The driving circuit for a switching element of the corresponding type is configured to apply a control voltage to an input terminal, which is set in advance according to the type of the switching element to be connected. When the negative voltage becomes higher, a faster switch-off process is achieved and the advantage that the heat development is reduced is correspondingly greater. However, switching elements are classified into a current-operated type and a voltage-operated type, and the voltage applicable to the input terminal differs depending on the type of the switching element. Therefore, a dedicated drive circuit corresponding to the type of the switching element is required, which must be configured. As a result, there is a problem that the type of substrates on which a drive circuit is mounted is increasing.

The present invention has been made to solve the above-described problem, and therefore, an object of the present invention is to provide a driving circuit for a switching element configured to automatically set a driving voltage to be applied to an input terminal regardless of whether the switching element is a voltage-driven type or a current-driven type.

Another object of the present invention is to obtain a power conversion device including the drive circuit for a switching element, an elevator device including the power conversion device and a method for driving a switching element.

the solution of the problem

The present invention provides a driving circuit for a switching element: a determination power supply unit configured to apply a voltage with a set voltage value to an input terminal of the connected switching element with an unknown driving type, to thereby turn on the switching element; a voltage measurement determination unit configured to measure a voltage value at the input terminal of the switching element in an ON state, thereby determining the switching element as a voltage-driven type when the measured voltage value is equal to or larger than a reference voltage value and as a current-driven type if the measured voltage value is less than the reference voltage value; a drive voltage generation unit configured to apply a drive voltage, which is a voltage adapted to a determination result in the voltage measurement determination unit, to the input terminal of the switching element; and a changeover switch configured to switch the determination power supply unit and the voltage measurement determination unit interchangeably with the drive voltage generation unit, to thereby connect to the input terminal of the switching element.

Furthermore, the present invention also includes a power conversion device including the control circuit for a switching element, an elevator device including the Power conversion device and a method for driving a switching element.

Beneficial effects of inventions

According to the present invention, the driving circuit for a switching element has a configuration which enables the driving circuit to identify a driving voltage suitable for the driving type of a switching element and which is capable of sharing a circuit regardless of the driving type.

Figure list

• 1 12 is a block diagram illustrating a configuration of a driving circuit for a switching element in an elevator device according to a first embodiment of the present invention.
• 2nd shows diagrams for illustrating a current-driven switching element and a voltage-driven switching element.
• 3rd FIG. 11 is a diagram illustrating the input terminal voltage characteristic of a current-driven type switching element and a voltage-driven type switching element and a reference voltage value Vref of an input terminal voltage measurement determination unit in the first embodiment of the present invention.
• 4th Fig. 14 is diagrams showing the definitions of a voltage Vic of a base drive unit of the current-driven type switching element and a voltage Viv of a gate drive unit of the voltage-driven type switching element in the first embodiment of the present invention.
• 5 10 is a diagram illustrating the waveforms of the voltages Vic and Viv to be applied to the switching elements of the base drive unit and the gate drive unit, respectively, in the first embodiment of the present invention.
• 6 10 is a block diagram illustrating a configuration of a driving circuit for a switching element in an elevator device according to a second embodiment of the present invention.
• 7 FIG. 12 is a diagram illustrating an example of a driving circuit power supply unit in the second embodiment of the present invention, in which the driving circuit power supply unit includes a switching power supply.
• 8th 10 is a diagram illustrating another example of a drive circuit power supply unit in the second embodiment of the present invention, in which the drive power supply unit includes a linear power supply.
• 9 12 is a diagram illustrating an example of a negative voltage generating unit in the second embodiment of the present invention.
• 10th 10 is a block diagram illustrating a configuration of a driving circuit for a switching element in an elevator device according to a third embodiment of the present invention.
• 11 FIG. 11 is a diagram illustrating an example of a configuration for controlling the driving circuits for a switching element in each of the embodiments of the present invention.

Description of the embodiments

A drive circuit for a switching element and the like according to embodiments of the present invention will now be described with reference to the drawings. In each of the embodiments, the same or corresponding parts are denoted by the same reference symbols, and the overlapping description thereof is omitted.

First embodiment

1 12 is a block diagram illustrating a configuration of a driving circuit for a switching element in an elevator device according to a first embodiment of the present invention. In 1 is the control circuit for a switching element as a control unit 8th shown. The present invention also includes a power conversion device 200 including the control unit 8th and a switching element 2nd . The present invention further includes an elevator device drive circuit 00 including the power conversion device 200 , a lifting machine 1 by the power conversion device 200 is driven, as well as a cabin CA and a counterweight CW that have two ends one on the hoist 1 suspended main rope MR are connected.

In 1 becomes the lifting machine 1 driven in rotation to the car CA and the counterweight CW with two ends of the around the Lifting machine 1 main rope MR are connected to raise and lower in opposite, different directions. The lifting machine 1 is through the power conversion device 200 including a three-phase inverter. The power conversion device 200 contains a variety of switching elements 2nd . The power conversion device 200 from 1 contains six switching elements 2nd for three-phase alternating current.

To each of the switching elements 2nd is one of several control units 8th connected with the same configuration. In each of the control units 8th the control type of the switching element is indefinite when the elevator device is first switched on, and at this point the switching element 2nd through a switch SW1 to a switching element determination power supply unit 3rd connected as in 1 shown. In this case, accordingly, a voltage from the switching element determination power supply unit 3rd input to an input terminal IPT. The input terminal IPT is a basic terminal or a gate terminal. To the input terminal IPT of the switching element 2nd becomes an input terminal voltage measurement determination unit 4th as well as the determination power supply unit 3rd connected. The voltage measurement determination unit 4th uses a measuring circuit 4a to measure a voltage generated at the input terminal and uses a determination circuit 4b to determine whether the switching element 2nd is a current-driven type or a voltage-driven type. The voltage measurement determination unit 4th is with a control switch unit 5 connected, and a determination result in the voltage measurement determination unit 4th is connected to the control switching unit 5 sent. The control switching unit 5 switches between a gate driver based on the determination result 6 and a basic control unit 7 that with the control switching unit 5 are connected to. After a drive voltage has been identified through this series of steps, the switching element 2nd through the switch SW1 from the destination power unit 3rd switched off and with the side of the control switching unit 5 connected. The switching element 2nd becomes in accordance with a drive signal of the gate drive unit 6 or the basic control unit 7 controlled for opening / closing, thereby the lifting machine 1 to drive. The lifting machine 1 is set in rotation. This causes the cabin CA and the counterweight CW Travel up and down in the opposite direction and the elevator device is operated by moving up and down.

The gate drive unit 6 , the basic control unit 7 and the drive switching unit 5 form a drive voltage generation unit 15 .

The changeover switch SW1 can be done manually or in accordance with a control signal from the drive switching unit 5 or be switched by an external control unit.

The switching element 2nd consists of a current-driven transistor (bipolar transistor or similar) according to the illustration (a) of 2nd and a voltage-driven transistor (insulated gate bipolar transistor (IGBT) or the like) according to the illustration (b) of 2nd . To the input terminal IPT of the switching element 2nd is a voltage from a power supply PS of the switching element determination power supply unit 3rd through an internal resistor R created.

In resistance R a current flows when the switching element 2nd the electricity-driven type 2A is. The voltage at the input terminal therefore saturates at a constant voltage VBE with increasing voltage Vin applied, and VBE <Vin is determined. The voltage VBE is usually 2.5 V to 3.5 V.

If the switching element 2nd however, the voltage-driven type 2 B is in resistance R flowing current is smaller than the current-driven type 2A . The voltage at the input terminal therefore increases in proportion to an applied voltage Vcc, and VGE≈Vin is set.

This difference is in 3rd shown. The axis of abscissa indicates the input voltage Vin and the axis of ordinate indicates the base emitter voltage VBE and the gate emitter voltage VGE.

From the destination power unit 3rd applied voltage is set to the voltage Vin at which the input terminal of the switching element 2nd , which is the current-driven type at which the constant voltage VBE reaches saturation. The voltage Vin is set to 5 V, for example.

If the switching element 2nd the electricity-driven type 2A is the application of the voltage Vcc from the determination power supply unit 3rd the input terminal to VBE (sat) as indicated by a dashed line 2AA from 3rd is shown. If the switching element 2nd the voltage-driven type 2 B on the other hand, the input terminal fulfills VGE (ref) ≈Vin, as indicated by a solid line 2BB from 3rd is shown. This enables the determination unit 4th for voltage measurement by comparing the values of these voltages with a reference voltage value Vref using the determination circuit 4b , which contains a comparator or the like, determine whether the switching element 2nd the electricity-driven type 2A or the voltage-driven type 2 B and output the result as a determination result signal.

If the switching element 2nd the electricity-driven type 2A is the heat generation of the resistance increases R as a positive voltage associated with the increase in voltage Vic from the base drive unit 7 as in part (a) of 4th shown, is created. It is therefore preferable that the voltage Vic is a minimum positive voltage or the lowest possible positive voltage through which the switching element 2nd , which is the powered type, can be turned on.

If the switching element 2nd however, the voltage-driven type 2 B is a faster turn-on and a greater advantage that the heat generation is reduced is achieved as a positive voltage when the voltage Viv from the gate drive unit 6 as in part (b) of 4th shown increases. It is therefore preferable that the voltage Viv be at a maximum positive voltage or as high a positive voltage as possible within the range of the withstand voltage of the switching element 2nd which is the voltage driven type.

If the switching element 2nd the electricity-driven type 2A is as in part (a) of 4th shown, the faster turn-off is achieved by a negative voltage that is applied when the voltage Vic from the base drive unit 7 increases. If the switching element 2nd the part (b) of 4th voltage shown, the faster turn-off is achieved by a negative voltage that is applied when the voltage Viv from the gate drive unit 6 increases. Since this increases the advantage that the heat development is reduced, a maximum negative voltage in the range of the withstand voltage is applied. However, the maximum negative voltage varies between the powered type 2A and the voltage-driven type 2 B , since the withstand voltage is lower when the switching element 2nd the electricity-driven type 2A than when the switching element 2nd the voltage-driven type 2 B is.

For example, the withstand voltage of the current-driven type 2A is -7 V and the withstand voltage of the voltage-driven type 2B is -20 V.

That of the basic control unit 7 applied voltage Vic and that from the gate drive unit 6 applied voltage Viv have different voltage values, an example of which is in 5 shown. The dashed line 2AA indicates the voltage Vic and the solid line 2BB indicates the voltage Viv.

The gate drive unit 6 and the basic control unit 7 both determine the time of ON / OFF activation of the switching element 2nd from a switching control signal SCS for the switching element 2nd which is an external signal to provide a positive or negative voltage. If the determination result in the determination unit 4th for the voltage measurement is the current driven type, in the case of a positive voltage and in the case of a negative voltage, a voltage is supplied which is lower than that when the switching element 2nd is the voltage-driven type. In other words, a drive voltage is supplied which has a smaller voltage in amplitude than that when the switching element 2nd the voltage driven type is regardless of whether the drive voltage is a positive or negative voltage.

The control switching unit 5 thus switches on the basis of the determination result signal of the voltage measurement determination unit 4th to the gate drive unit 6 or the basic control unit 7 to the switching element 2nd with the basic control unit 7 to connect when the switching element 2nd the electricity-driven type 2A and with the gate drive unit 6 when the switching element 2nd the voltage-driven type 2 B is. The control circuit for the switching element is automatically set in this way.

Second embodiment

6 11 is a block diagram illustrating a configuration of a driving circuit for a switching element included in an elevator device according to a second embodiment of the present invention. In the first embodiment described above, both the gate driver unit 6 as well as the basic control 7 as in 1 shown provided. The drive circuit can also be configured so that, as in 6 shown, a drive circuit power supply unit 16 and a negative voltage generating unit 17th in a drive voltage generation unit 15 be configured and that a voltage Vc the drive circuit power supply unit 16 and a voltage V- of the negative voltage generating unit 17th using the determination result signal of the voltage measurement determination unit 4th can be set. In particular, the drive circuit is configured so that the drive circuit power supply unit 16 and the negative voltage generating unit 17th instead of the gate drive unit 6 and the basic control unit 7 are provided and the voltage Vc and the voltage V- are set. As described later, “V-” means a voltage by which a reverse bias is applied between the base and the emitter or between the gate and the emitter of the switching element. With this configuration, too, the same operation as in the first embodiment described above is carried out. This configuration enables the current-driven type and the voltage-driven type to share parts, and thus the number of parts and the area occupied by a substrate can be reduced. The remaining components in 6 are essentially the same as in 1 .

7 FIG. 12 is a diagram illustrating an example of the drive circuit power supply unit 16 in the drive voltage generation unit 15 the second embodiment in which the drive circuit power supply unit 16 contains a circuit power supply. The circuit power supply is a method of setting an output voltage by adjusting the width of a switching pulse that is in a power supply switching element PSSW is entered. The width of the switching pulse of the power supply switching element PSSW using the determination result signal of the voltage measurement determination unit 4th set accordingly, and the tension Vc the drive circuit power supply unit 16 is set as a result of this.

A pulse width adjustment unit 18th for the power supply switching element PSSW contains a carrier wave generating unit 19th , a reference voltage generation unit 22 which are the constant voltage elements 20 and 21 contains, and a comparator 23 , the carrier wave of the carrier wave generating unit 19th and a reference voltage Vz the reference voltage generating unit 22 compares. The output signal of the comparator 23 is a switching pulse, and the switching pulse is a high level output for the duration in which the carrier wave voltage is higher than the reference voltage Vz is. The constant voltage element 21 is by a switching element 24th using the determination result signal of the voltage measurement determination unit 4th short-circuited. This changes the reference voltage Vz to thereby change the width of the switching pulse. This way the tension Vc the drive circuit power supply unit 16 set.

The reference voltage generation unit 22 forms a constant voltage circuit that is able to switch voltages. A choke coil CC, a capacitor C1 and a diode D1 on the output side of the power supply switching element PSSW form a low pass filter LPF1 .

The voltage Vc the drive circuit power supply unit 16 is, for example, a difference between the high voltage and the low voltage in 5 . The voltage Vc is 13 V when the switching element 2nd the electricity-driven type 2A and 25 V when the switching element 2nd the voltage-driven type 2 B is.

When the drive circuit power unit 16 contains a down-switching power supply, an input voltage is represented by "Vi", a switching cycle by "t" and a high signal width of a pulse by "twh", Vc is expressed as VC = twh / txVi.

If the input voltage Vi is set to DC 100 V, the high signal width of the switching pulse is set to a 0.13 times the cycle width by the voltage Vc the drive circuit power supply unit 16 to bring to 13 V. Around Vc to 25 V, the high signal width of the switching pulse is set to 0.25 times the low signal width.

When the carrier wave is set to a peak voltage Vp, twh is expressed as twh = tt / (2xVp) x (Vz + Vp). If the carrier wave is a triangular wave with a peak voltage Vp of 10 V, the reference voltage Vz set to 7.4 V to the voltage Vc the drive circuit power supply unit 16 to 13 V, ie to bring the high signal width of the switching pulse to a width of 0.13 times the cycle. Around Vc Bringing it to 25 V, on the other hand, becomes the reference voltage Vz set to 5.0 V.

If the constant voltage element 20 to 5.0 V, the other constant voltage element 21 is set to 2.4 V and the switching element 2nd as a powered type 2A using the determination result signal of the voltage measurement determination unit 4th is determined, the switching element 24th switched off. This will make the reference voltage Vz changed to 7.4 V so that Vc is brought to 13 V.

If the switching element 2nd than the voltage-driven guy 2 B on the other hand, the constant voltage element is determined 21 by switching on the switching element 24th shorted what the reference voltage Vz changes to 5.0 V and thus Vc to 25 V.

The drive circuit power supply unit described in the above description 16 contains a step-down power supply. The voltage Vc the drive circuit power supply unit 16 can, however, by a similar configuration using the determination result signal of Voltage measurement determination unit 4th can also be set when the control power supply unit 16 includes an upshift power supply and if the control power supply unit 16 contains an RCC circuit power supply.

8th FIG. 12 is a diagram illustrating an example of the drive circuit power supply unit 16 in the drive circuit generation unit 15 the second embodiment in which the drive circuit power supply unit 16 contains a linear power supply. The linear power supply uses a method of adjusting an output voltage by the voltage of an input terminal of a variable resistance circuit 25th is set. The voltage Vc the drive circuit power supply unit 16 Therefore, by adjusting the voltage of the linear power supply using the determination result signal of the voltage measurement determination unit 4th set.

The constant tension elements 26 and 27 are with the input terminal of the variable resistance circuit 25th connected. The voltage of the linear power supply is obtained by short-circuiting the constant voltage element 27 through a switching element 28 using the determination result signal of the voltage measurement determination unit 4th set. The voltage Vc the drive circuit power supply unit 16 is set this way.

When there is a voltage between the input and output terminals of the variable resistance circuit 25th by " Vs “, The tension of the constant tension element 26 by " Vz1 “And the voltage of the constant voltage element 27 is represented by "Vz2", the voltage Vc the drive circuit power supply unit 16 expressed as Vc = Vs + Vz1 + Vz2.

The voltage Vs between the input terminal and the output terminal of the variable resistance circuit 25th is generally 0.6 V. The voltage of the constant voltage element 27 is expressed as "Vc = Vs + Vz1 + Vz2", the voltage Vc the drive circuit power supply unit 16 is expressed as Vc = Vz1 + Vz2. Accordingly, the constant voltage element 26 to 12.4 V and the other constant voltage element 27 set to 12 V and if the switching element 2nd as a powered type 2A using the determination result signal of the voltage measurement determination unit 4th is determined, the switching element 28 switched on. This will make the constant voltage element 27 shorted so that Vc is brought to 13 V.

If the switching element 2nd as a voltage-driven type 2 B is determined against Vc by switching off the switching element 28 brought to 25 V.

A constant voltage circuit 267 which are the constant voltage elements 26 and 27 contains is a constant voltage circuit that is able to switch the voltages.

The variable resistance circuit 25th contains a transistor Tr25, in which a base and a collector through a resistor R25 are interconnected. The collector terminal of the transistor Tr25 is connected to an input terminal of the drive circuit power supply unit 16 is connected, and the emitter terminal of the transistor Tr25 is connected to an output terminal of the drive circuit power supply unit 16 connected.

9 FIG. 12 is a diagram illustrating an example of a configuration of the negative voltage generation unit 17th in the drive voltage generation unit 15 the second embodiment. The drive circuit power supply unit 16 in 9 is the drive circuit power supply unit 16 that related to 6 to 8th is described. A control circuit 29 is a circuit that has a drive voltage for turning the switching element on / off 2nd switches in accordance with the switching control signal SCS from the outside. In 6 to 8th is the control circuit 29 in the drive circuit power supply unit 16 contain.

If the switching element 2nd the control circuit switches 29 a switching element 30th off and the other switching element 31 a. The input terminal of the switching element 2nd is consequently determined by the voltage V- of the negative voltage generating unit 17th biased in the reverse direction. As described above, a voltage by which a reverse bias is applied is indicated by "V-".

The negative voltage generating unit 17th puts the tension Vc the drive circuit power supply unit 16 via a current limiting resistor RR to a capacitor C and a constant voltage circuit 323 on, which is connected in parallel to capacitor C and the constant voltage elements connected in series 32 and 33 contains. The constant voltage element 33 is then by a switching element 34 short-circuited to thereby the voltage V- of the negative voltage generating unit 17th adjust.

If the constant voltage element 32 to 4V, the other constant voltage element 33 is set to 6V and the switching element 2nd using the determination result signal of the voltage measurement determination unit 4th as a powered type 2A is determined, the constant voltage element 33 by switching on the switching element 34 is short-circuited, and V- is consequently brought to 4 V.

If the switching element 2nd as a voltage-driven type 2 B V- is determined, however, by switching off the switching element 34 brought to 10 V.

Regarding the reverse bias, there is a connection point between the switching element 30th and the switching element 31 as input terminal IPBG of the switching element 2nd with the base terminal or the gate terminal of the switching element 2nd connected. An output terminal of the negative voltage generating unit identified by “V-” 17th is the input terminal IPE of the switching element 2nd with the emitter terminal of the switching element 2nd connected.

If the switching element 2nd the control circuit switches 29 the switching element 30th off and the switching element 31 one so that the input terminal IPBG of the switching element 2nd is brought to 0 V. In contrast, a positive voltage indicated by "V-" is applied to the input terminal IPE, thereby the switching element 2nd load in the blocking direction. This causes a relatively negative voltage to be applied to the input terminal IPBG of the switching element 2nd .

The constant voltage circuit 323 including the constant voltage elements 32 and 33 is a constant voltage circuit that can switch voltages.

Third embodiment

10th 10 is a block diagram illustrating a configuration of a driving circuit for a switching element included in an elevator device according to a third embodiment of the present invention. In the in 1 The configuration of the control circuit for a switching element is shown for each switching element 2nd the destination power unit 3rd and the input terminal voltage measurement determination unit 4th intended. In the in 10th shown control circuit for a switching element are the determination power supply unit after switching on the elevator 3rd and the voltage measurement determination unit 4th one after the other from a switching element 2nd and the control switching unit 5 in a control unit 8th to another switching element 2nd and the drive switching unit 5 in another control unit 8th switched. This allows the elevator to use a single destination power supply 3rd and a single voltage measurement determination unit 4th operate in the same manner as in the above-described embodiments.

For this purpose, the control circuit for a switching element according to the third embodiment with the control unit 8th , namely the drive voltage generation unit 15 , for each of several switching elements 2nd Mistake. The control circuit is also provided with a common switching mechanism, the common changeover switch CSW1 and CSW2 which contains a single destination power unit 3rd and a single voltage measurement determination unit 4th with one of the several switching elements 2nd and one of the plurality of drive voltage generation units 15 connects by using a switching element 2nd and a drive voltage generation unit 15 to another switching element 2nd and another drive voltage generation unit 15 switches. The common switch CSW1 is for each switching element 2nd provided and connects the switching element 2nd with its own drive voltage generation unit 15 or with the common destination power supply unit 3rd and the one voltage measurement determination unit 4th by switching between the drive voltage generation unit 15 and the common destination power unit 3rd and the one voltage measurement determination unit 4th . The common switch CSW2 is in unity 4th provided for determining the voltage measurement and connects the input terminal voltage measurement determination unit 4th with one of the drive voltage generation units 15 by being driven by a drive voltage generating unit 15 to another drive voltage generation unit 15 switches.

With this configuration, parts can be shared, which can reduce the number of parts and the area occupied by a substrate.

The switch SW1 in the first and second embodiment, the common switch CSW1 and CSW2 in the third embodiment as well as further switches can be switched manually or automatically. An example of automatic switching is in 11 shown in which a switching signal SWS is supplied by a control device COD, which is the overall control of the power conversion device 200 or the elevator device 400 together with the switching control signal SCS for controlling the switching element 2nd and other signals, and the switch SW1 and the common switch CSW1 and CSW2 can be switched by the switching signal SWS.

For example, if the controller COD is a hardware device, a processing circuit corresponds to a single circuit, a composite circuit, a programmed processor, an ASIC, an FPGA, or a combination thereof.

When the controller COD is a CPU, the controller COD includes a processor and memory and is implemented by software, firmware, or a combination of software and firmware. Software and firmware are written as programs, which are then stored in a memory. The processor, which is a processing circuit, reads and executes the programs stored in memory, thereby implementing processing functions.

The above descriptions deal with cases of applying the present invention to an elevator. However, the present invention is also applicable to other driving circuits for a switching element and other power conversion devices.

Furthermore, the present invention is not limited to each of the above-mentioned embodiments, and the present invention encompasses all possible combinations of these embodiments.

An elevator has a long lifespan and parts are replaced for maintenance until the lifespan expires. The parts include a switching element. In recent years, current-driven switching elements have been difficult to obtain and are therefore being replaced by voltage-driven switching elements. Dedicated drive circuits corresponding to the types of switching elements are required in the prior art. The substrates on which the control circuits are mounted must also be replaced at the same time as the switching elements are replaced. In the present invention, it is determined whether a connected switching element is a voltage-driven or a current-driven one to automatically set a control voltage to be applied to an input terminal. The automatic adjustment of the control voltage to be applied to the input terminal based on the driving type of the switching element is used to also apply a negative voltage to accelerate the OFF operation. This enables the elevator to use a substrate on which the drive circuit is mounted as it is without the need for adjustment, and helps reduce maintenance costs and the types of substrates on which the drive circuits are mounted , reduce and integrate.

Reference list

1 lifting machine, 2 switching element, 3 switching element determination power supply unit (determination power supply unit), 4 input terminal voltage measurement determination unit (voltage measurement determination unit), 4a measuring circuit, 4b determination circuit, 5 control switching unit, 6 gate control unit, 7 basic control unit, 8 control unit, 15 control voltage generation generator unit, 19 pulse power supply generating unit, 19 pulse power supply generating unit, pulse generator unit , 20 constant voltage element, 21 constant voltage element, 22 reference voltage generating unit, 23 comparator, 24 switching element, 25 variable resistance circuit, 26 constant voltage element, 27 constant voltage element, 28 switching element, 29 control circuit, 30 switching element, 31 switching element, 32 constant voltage element, 33 constant voltage element, power switching device, 34 switching element, 34 switching element 267 constant voltage sc attitude, 323 constant voltage circuit, 400 elevator device, CSW1, CSW2 common switch, COD control device

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP H0613869 A [0003]

Claims (12)

A driving circuit for a switching element comprising: a determination power supply unit configured to apply a voltage having a set voltage value to an input terminal of the connected switching element with an unknown control type, thereby turning on the switching element; a voltage measurement determination unit configured to measure a voltage value at the input terminal of the switching element in an ON state, thereby determining the switching element as a voltage driven type when the measured voltage value is equal to or larger than a reference voltage value, and as one current driven type when the measured voltage value is less than the reference voltage value; a drive voltage generation unit configured to apply a drive voltage, which is a voltage adapted to a determination result in the voltage measurement determination unit, to the input terminal of the switching element; and a changeover switch configured to switch the determination power supply unit and the voltage measurement determination unit interchangeably with the driving voltage generation unit, to thereby connect to the input terminal of the switching element. The control circuit for a switching element after Claim 1 wherein the drive voltage generation unit comprises: a base drive unit configured to apply the drive voltage to the power-driven type switching element; a gate drive unit configured to apply the drive voltage to the voltage-driven type switching element; and a drive switching unit configured to connect the base drive unit to the input terminal of the switching element when the determination result in the voltage measurement determination unit is the current-driven type, and to connect the gate drive unit to the input terminal of the switching element when the determination result is the voltage-driven type. The control circuit for a switching element after Claim 2 , wherein the base drive unit and the gate drive unit are configured: to apply a drive voltage lower than that when the determination result in the voltage measurement determination unit is the current driven type than the determination result is the voltage driven type; apply a negative voltage to the input terminal of the switching element when the switching element is turned off; and apply a negative voltage when the determination result in the voltage measurement determination unit is the current-driven type that is lower than that when the determination result is the voltage-driven type. The control circuit for a switching element after Claim 1 , wherein the drive voltage generation unit is configured to apply a lower drive voltage than when the determination result in the voltage measurement determination unit is the current-driven type than when the determination result is the voltage-driven type. The control circuit for a switching element after Claim 1 or 4th wherein the drive voltage generation unit further comprises: a power supply switching element configured to perform voltage adjustment switching of an input voltage to thereby output the adjusted input voltage as the drive voltage; and a pulse width setting unit configured to output a switching pulse to the power supply switching element and to adjust and output a pulse width according to the determination result in the voltage measurement determination unit. The control circuit for a switching element after Claim 1 or 4th wherein the drive voltage generating unit further comprises: a variable resistance circuit in which a base and a collector of a transistor are connected through a resistor, an input voltage is input to a collector terminal, and an output voltage is supplied from an emitter terminal; and a variable voltage and constant voltage circuit configured to change the input voltage of the variable resistance circuit in accordance with the determination result in the voltage measurement determination unit. The control circuit for a switching element after Claim 5 or 6 , wherein the drive voltage generation unit further includes a negative voltage generation unit configured to apply a negative voltage to the input terminal of the switching element when the switching element is turned off, and when the determination result in the voltage measurement determination unit is the driven type generate negative voltage that is lower than that when the determination result is the voltage driven type. The control circuit for a switching element after Claim 7 wherein the negative voltage generation unit is configured, when the switching element is turned off, to generate a negative voltage in the input terminal by applying a reverse bias to the switching element. The control circuit for a switching element according to one of the Claims 1 to 8th , the switching element comprising a plurality of switching elements, the drive voltage generation unit comprising a plurality of drive voltage generation units, each of the plurality of drive voltage generation units being provided for each of the plurality of switch elements, and the drive circuit further comprising a common switching mechanism configured to configure one To connect the determination power supply unit and the one voltage measurement determination unit so that it can be switched with the plurality of switching elements and the plurality of drive voltage generation units. A power conversion device comprising: the driving circuit for a switching element according to one of the Claims 1 to 9 ; and a switching element driven and controlled by the switching element driving circuit. An elevator device comprising: the power conversion device to Claim 10 ; a hoist driven by the power conversion device; and a cabin and a counterweight connected to two ends of a main rope suspended from the hoist. A method for driving a switching element, comprising: Applying a voltage with a set voltage value to an input terminal of the switching element, thereby turning on a connected switching element with an unknown drive type; Measuring a voltage value at the input terminal of the switching element in an ON state and determining the switching element as a voltage-operated type when the measured voltage value is equal to or greater than a reference voltage value and as a current-operated type when the measured voltage value is smaller than the reference voltage value; and Applying a control voltage adapted to a determination result to the input terminal of the switching element.

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