JP2023057866A - Engine-driven generator - Google Patents

Abstract

To easily switch a maximum output frequency and a rating voltage of an engine-driven generator so as to be an appropriate combination in accordance with a specification of a connected motor apparatus.SOLUTION: In an inverter 2, an external connection terminal 22 for maximum output frequency setting is provided for setting a maximum output frequency to a first maximum output frequency (58 Hz, for an example) in a first connection state (where terminals 22c and 22a are not connected) and setting the maximum output frequency to a second maximum output frequency (48 Hz, for an example) in a second connection state (where the terminals 22c and 22a are connected). In an automatic voltage regulator (AVR) 43 in a generator body, an external connection terminal 44 for rating output voltage setting is provided for setting a rating voltage to a first rating output voltage (220 V) in a first connection state (where terminals 44c and 44a are connected) and setting the rating output voltage to a second rating output voltage (200 V) in a second connection state (where the terminals 44c and 44b are not connected). The connection states of the external connection terminal 22 in the inverter 2 and the external connection terminal 44 in the AVR can be simultaneously changed over by a changeover switch 5 provided in a control panel 7.SELECTED DRAWING: Figure 2

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine-driven generator, and more particularly to an inverter-embedded engine-driven generator with a variable output frequency.

The portable engine-driven generator 300, in which the engine 303 and the generator main body 304 driven by the engine 303 are accommodated, for example, in a common soundproof box 308, is particularly suitable for outdoor use such as construction sites and event venues due to its portability. It is widely used when it is necessary to secure a power supply in

In such an engine-driven generator 300, as shown in FIG. 10, a non-illustrated device (load) connected to the engine-driven generator 300 is equipped with a three-phase induction motor like a submersible pump. In the case of a device (such device is hereinafter referred to as "motor device"), in order to make the output frequency for this motor device variable, the output of the generator main body 304 is connected to the three-phase output line 351 (in the illustrated example, 351a) to the inverter 302, and after the inverter 302 performs frequency conversion, it is possible to output to the motor device connected to the three-phase output terminal block 361 ( Claim 3 of Patent Document 1, see FIG. 1).

JP 2012-110098 A

In the above-described engine-driven generator 300 equipped with the inverter 302, when the operator operates the frequency setting means 321 such as a dial switch provided on the control panel 307 to set the frequency, the inverter 302 changes the output of the generator body 304. , by converting it to a set frequency and outputting it, the rotational speed of the motor device can be varied according to the set frequency. It is possible to control the operation of the motor equipment according to the situation, such as driving the submersible pump at a rotation speed that generates a drainage amount that is in balance with the amount of water that enters.

Here, for general-purpose motor devices that are driven by receiving power supplied from commercial power sources, those designed on the premise that they will operate at 60 Hz/220 V and those designed to operate at 50 Hz/200 V correspond to the frequencies of commercial power sources. There are some that are designed on the premise that they will work with

On the other hand, in the above-mentioned engine-driven generator equipped with an inverter, the above-mentioned dial switch 321 etc. can be used to adapt to the connection of any motor device with specifications of 60Hz/220V or 50Hz/200V. The maximum frequency (maximum output frequency) that can be generated is generally set to correspond to the higher frequency of 60 Hz.

Therefore, it is possible to increase the output frequency to a maximum of 60 Hz by operating the dial switch 321 described above. If the output frequency exceeds 50Hz, overcurrent will flow to the motor equipment, which may lead to failure such as burning.

In order to deal with such a problem, the maximum output frequency of the inverter 302 is set to 60 Hz as an example when a 60 Hz specification motor device is connected, but when a 50 Hz specification motor device is connected, It is also conceivable to change the setting of the maximum output of the inverter 302 according to the specifications of the connected motor device, such as setting the maximum output frequency of the inverter to 50 Hz.

However, in order to change the setting of the maximum output frequency of the inverter 302, a part of the hood of the soundproof box 308 is removed to expose the inverter 302, and the operation panel provided on the inverter 302 is operated. Work to change the settings is required.

In addition, motor equipment used at a frequency of 50 Hz has a rated voltage of 200 V, and motor equipment used at a frequency of 60 Hz has a rated voltage of 220 V, so the maximum output depends on the specifications of the connected motor equipment. When changing the frequency setting, it is also necessary to change the setting of the rated output voltage of the generator body 304 .

However, even when changing the rated output setting, the automatic voltage regulator (AVR) 343 that controls the output voltage of the generator body 304 is exposed by removing a part of the hood of the soundproof box 308. It is extremely troublesome to perform such work every time the motor device is replaced.

Therefore, there is a demand for an engine-driven generator that can be relatively easily and accurately changed with the correct combination of maximum output frequency and rated voltage according to the specifications of the connected motor equipment.

Therefore, the present invention has been made to solve the above-mentioned drawbacks of the prior art. In an engine-driven generator with a built-in inverter, the engine It is an object of the present invention to provide an engine-driven generator in which settings on the side of the driven generator can be easily changed by an appropriate combination and by extremely simple work without causing setting errors.

Means for solving the problems are described below together with the symbols used in the mode for carrying out the invention. This code is for clarifying the correspondence between the description of the claims and the description of the mode for carrying out the invention, and needless to say, it is used restrictively to interpret the technical scope of the present invention. It is not something that can be done.

In order to achieve the above object, the engine-driven generator 1 of the present invention
A generator body 4, an engine 3 that drives the generator body 4, a three-phase output terminal block 62 that outputs the power generated by the generator body 4, and between the generator body 4 and the three-phase output terminal block 62 , an inverter 2 that converts the frequency of the three-phase AC power output by the generator body 4 and outputs it to the three-phase output terminal block 62, and an automatic voltage adjustment that controls the output voltage of the generator body 4 In the engine-driven generator 1 equipped with a generator (AVR) 43,
Maximum output frequency setting means for setting the maximum output frequency of the inverter 2 to a predetermined first maximum output frequency (58 Hz as an example) or a predetermined second maximum output frequency (48 Hz as an example) 22 (22a to 22d) are provided,
In the automatic voltage regulator (AVR) 43, the setting of the rated output voltage of the generator body 4 controlled by the automatic voltage regulator (AVR) 43 is set to a predetermined first rated output voltage (220 V as an example), or A rated output voltage setting means 44 (44a to 44c) for setting a predetermined second rated output voltage (200V as an example) is provided,
The maximum output frequency setting means 22 (22a to 22d) and the rated output voltage setting means 44 (44a to 44c) are operated in conjunction to set the maximum output frequency to the first maximum output frequency (58 Hz). At the same time, when setting the rated output voltage to the first rated output voltage (220 V) and setting the maximum output frequency to the second maximum output frequency (48 Hz), the rated output The interlocking operation means 5 for setting the voltage to the second rated output voltage (200 V) is operably provided on the control panel 7 of the engine-driven generator 1 (Claim 1: 2 to 4).

When the inverter 2 is in a predetermined first connection state (as an example, a state in which the common terminal 22c and the first input terminal 22a are disconnected) as the maximum output frequency setting means 22, the maximum output frequency is set to the first frequency. 1 maximum output frequency (58 Hz), and when a predetermined second connection state (for example, a state in which the common terminal 22c and the first input terminal 22a are connected), the maximum output frequency is set to the second maximum output frequency ( 48 Hz), providing an external connection terminal 22 (22a to 22d) for setting the maximum output frequency,
In the automatic voltage regulator (AVR) 43, as the rated output voltage setting means 44, when a predetermined first connection state (for example, a state in which the common terminal 44c and the first input terminal 44a are connected), the rated output When the voltage is set to the first rated output voltage (220 V) and in a predetermined second connection state (for example, a state in which the common terminal 44c and the second input terminal 44b are connected), the rated output voltage is set to the second rated output voltage. An external connection terminal 44 (44a to 44c) for setting the rated output voltage is provided to achieve the rated output voltage (200V),
The interlocking operation means 5 is
contacts (51a to 51c, 52a to 52c) connected to the maximum output frequency setting external connection terminal 22 and the rated output voltage setting external connection terminal 44, respectively;
The first contact points (51a to 51c, 52a to 52c) are connected so that the maximum output frequency setting external connection terminal 22 and the rated output voltage setting external connection terminal 44 are both in the first connection state. Switching position [see FIG. 2(A)],
A second connection is made between the contacts (51a to 51c, 52a to 52c) so that both the maximum output frequency setting external connection terminal 22 and the rated output voltage setting external connection terminal 44 are in the second connection state. The changeover switch 5 having a switching position [see FIG. 2(B)] may be used (Claim 2: see FIGS. 2 to 4).

The control panel 7 of the engine-driven generator 1 further displays the rated rotation speed of the engine 3 as a first rated rotation speed (1800 min ^-1 as an example) or a second rated rotation speed (1500 min ^-1 as an example). ), the rated rotational speed changing means 56 may be provided with an operating portion 57, 57' (Claim 3: see FIGS. 5 to 7).

If the engine 3 is an electronically controlled engine equipped with an engine control module (ECM) 31,
The engine control module (ECM) 31 switches the setting of the rated rotational speed of the engine 3 to a predetermined first rated rotational speed (1800 min ^-1 ) or a predetermined second rated rotational speed (1500 min ^-1 ) , a rated rotation speed setting means 32 (32a to 32c) is provided,
The interlocking operation means 5 interlocks the rated rotational speed setting means 32 together with the maximum output frequency setting means 22 and the rated output voltage setting means 44 to set the maximum output frequency to the first maximum. When setting the output frequency (58 Hz) and the rated output voltage to the first rated output voltage (220 V), simultaneously setting the rated rotation speed to the first rated rotation speed (1800 min ^-1 ),
When setting the maximum output frequency to the second maximum output frequency (48 Hz) and the rated output voltage to the second rated output voltage (200 V), at the same time the rated rotation speed is set to the second rated rotation speed (1500 min ^-1 ) (Claim 4: see FIGS. 3 and 4).

Similarly, if the engine 3 is an electronically controlled engine equipped with an engine control module (ECM) 31,
When the engine control module (ECM) 31 is in a predetermined first connection state (for example, a state in which the common terminal 32c and the first input terminal 32a are connected), the rated rotational speed is set to a predetermined first rated rotational speed ( 1800 min ⁻¹ ), and a predetermined second connection state (as an example, a state in which the common terminal 32c and the second input terminal 32b are connected), the rated rotation speed is set to a predetermined second rated rotation speed (1500 min ^{−1 )} . ¹ ), provide external connection terminals 32 (32a to 32c) for setting the rated rotation speed,
The changeover switch 5 is further provided with contacts (53a to 53c) connected to the external connection terminals 32 (32a to 32c) for setting the rated rotation speed,
When the selector switch 5 is set to the first switching position, the external connection terminals 32 (32a to 32c) for setting the rated rotation speed are set to the first connection state, and the selector switch 5 is set to the second switching position. The contacts (53a to 53c) may be connected so that the external connection terminals 32 (32a to 32c) for setting the rated rotation speed are in the second connection state (claim 5). : see Figures 3 and 4).

Furthermore, when the maximum output frequency is set to the first maximum output frequency (58 Hz), the base frequency of the inverter is set to the first base frequency at the same time as the maximum output frequency setting means 22 provided in the inverter 2. (60 Hz as an example), and when the maximum output frequency is set to the second maximum output frequency (48 Hz), the base frequency of the inverter is set to the second base frequency (50 Hz as an example) at the same time. , a base frequency setting function may be added (Claim 6: see FIG. 4).

In order to realize such a base frequency setting function, the maximum output frequency setting means 22 is arranged so that the maximum output frequency setting external connection terminals 22 (22a to 22d) are in the first connection state (for example, the common terminal 22c). When the input terminal 22a is disconnected), the maximum output frequency is set to the first maximum output frequency (58 Hz), the base frequency of the inverter 2 is set to the predetermined first base frequency (60 Hz), and the When in the second connection state (for example, a state in which the common terminal 22c and the input terminal 22a are connected), the maximum output frequency is set to the second maximum output frequency (48 Hz) and the base frequency of the inverter 2 is set to a predetermined frequency. It is configured to have two base frequencies (50 Hz) (Claim 7: see FIG. 4).

Due to the configuration of the present invention described above, the engine-driven generator 1 of the present invention has the following remarkable effects.

Interlocking operation means (switch) 5 for simultaneously changing the setting of the maximum output frequency of the inverter 2 and the setting of the rated output voltage of the automatic voltage regulator (AVR) 43 is provided on the control panel 7 of the engine-driven generator 1. By operating the interlocking operation means (switch) 5 provided on the control panel 7, the setting of the maximum output frequency of the inverter 2 and the setting of the rated output voltage of the generator body 4 can be simultaneously and appropriately performed. I was able to change it so that it would be a good combination.

As a result, by setting the first maximum output frequency to, for example, 58 Hz, the first rated output voltage to, for example, 220 V, the second maximum output frequency to, for example, 48 Hz, and the second rated output voltage to, for example, 200 V, three-phase output Depending on whether the specifications of the motor device M connected to the terminal block 62 are 60 Hz/220 V or 50 Hz/200 V, the hood of the soundproof box 8 is removed and the inverter 2 or automatic voltage regulator (AVR) 43 is connected. without directly operating to change the setting, just by operating the interlocking operation means (selector switch) 5 provided on the control panel 7, the setting on the engine driven generator 1 side can be changed to 58 Hz / 220 V or 48 Hz / It can be easily switched to 200V.

Also, when setting in this way, if the specification of the motor device M connected to the three-phase output terminal block 62 is 50 Hz/200 V, the second maximum output frequency (48 Hz) is used as the maximum output frequency/rated output voltage. / By selecting a combination of the second rated output voltage (200V), the output frequency is set to the second maximum output frequency (48Hz) even when the frequency setting means 21 composed of a dial switch or the like is operated at the maximum amount. However, by preventing the output of a frequency that exceeds the specification of the connected motor device M (50 Hz in the above example), damage to the motor device M can be prevented.

On the other hand, when the specifications of the motor device M connected to the three-phase output terminal block 62 are 60 Hz/220 V, the maximum output frequency/rated output voltage is the first maximum output frequency (58 Hz)/first rated output voltage By selecting the combination of (220V), the output frequency can be increased to the second maximum output frequency (58Hz) by operating the frequency setting means 21 consisting of a dial switch or the like to the maximum amount, and the connected motor equipment It is possible to increase the rotational speed to near the maximum within the specification of M.

The control panel 7 of the engine-driven generator 1 further changes the rated rotation speed of the engine 3 to the first rated rotation speed (1800 min ^-1 ) or the second rated rotation speed (1500 min ^-1 ), In the configuration in which the operation units 57 and 57' of the rated rotation speed changing means 56 are provided, not only the setting change of the maximum output frequency and the rated output voltage but also the setting change of the rated rotation speed of the engine 3 are provided on the control panel 7. This can be easily performed by operating the operating sections 57 and 57'.

Furthermore, when the engine 3 is an electronically controlled engine equipped with an engine control module (ECM) 31, the engine control module (ECM) 31 is provided with rated rotation speed setting means 32 (32a to 32c), The rated rotation speed setting means 32 (32a to 32c) can also be operated in conjunction with the maximum output frequency setting means 22 and the rated output voltage setting means 44 by the interlocking operation means (switch) 5 provided on the control panel 7. Thus, not only the maximum output frequency of the inverter 2 and the rated output voltage of the generator body 4, but also the rated rotation speed of the engine 3 can be set by operating the interlocking operation means (switch) 5 provided on the control panel 7. could be changed at the same time.

In addition, by enabling all these settings to be performed simultaneously by operating the interlocking operation means (changeover switch) 5, the maximum output frequency, rated output voltage, and rated rotation speed can be set in an incorrect combination. was able to prevent it.

Furthermore, when the maximum output frequency is set to the first maximum output frequency (58 Hz), the base frequency of the inverter 2 is set to a predetermined first base frequency (60 Hz) at the same time. and setting the base frequency of the inverter 2 to a predetermined second base frequency (50 Hz) at the same time that the maximum output frequency is set to the second maximum output frequency (48 Hz). By adding the function, by performing so-called "V/f constant control" based on the base frequency and base frequency voltage corresponding to the specifications of the motor device M connected to the three-phase output terminal block 62, the rotation speed It was possible to operate the motor device M at a constant torque even by changing .

In particular, the maximum output frequency setting external connection terminals 22 (22a to 22d) of the maximum output frequency setting means 22 are in a predetermined first connection state (for example, the common terminal 22c and the first input terminal 22a are disconnected). state), the maximum output frequency is set to the first maximum output frequency (58 Hz), the base frequency is set to the first base frequency (60 Hz), and a predetermined second connection state (for example, the common terminal 22c and When the first input terminal 22a is connected), the maximum output frequency is the second maximum output frequency (48 Hz) and the base frequency is the second base frequency (50 Hz). , the setting of the maximum output frequency and the rated output voltage, or the setting of the maximum output frequency, the rated output voltage, and the rated rotation speed of the engine can be simultaneously switched by operating the interlocking operation means (switch) 5, Furthermore, the setting of the base frequency and therefore the change of the output characteristics of the inverter could also be performed at the same time.

1 is an external perspective view of an engine-driven generator of the present invention; FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic illustration of an engine-driven generator of the present invention, in which (A) is a state in which the selector switch is in the first switching position (maximum output frequency 58 Hz/rated output voltage 220 V setting), and (B) is the selector switch in the first position. 2 State in switching position (maximum output frequency 48Hz/rated output voltage 200V setting). FIG. 4 is a schematic explanatory diagram showing a modified example of the engine-driven generator of the present invention; FIG. 5 is an explanatory diagram showing still another modification of the engine-driven generator of the present invention; Explanatory drawing of the structural example of a control panel. Explanatory drawing of a rated rotation speed change means. Explanatory drawing of the example of a change of a control panel (the example of a change of the part enclosed with the broken line in FIG. 5). FIG. 6 is an explanatory diagram of another modified example of the control panel (a modified example of the part surrounded by the dashed line in FIG. 5); Explanatory drawing of V/f constant control. A conventional engine-driven generator (corresponding to FIG. 1 of Patent Document 1).

The configuration of the present invention will be described below with reference to the accompanying drawings.

In the following explanation, the first and second maximum output frequencies of the inverter are set to 58 Hz/48 Hz, which are frequencies lower than the commercial power frequency of 60 Hz/50 Hz by a predetermined margin, as an example. Although it is possible to reliably prevent the output of frequencies exceeding the specifications of M (usually 60Hz / 50Hz), the first / second maximum output frequency is below the specifications of the connected motor device M ( 60 Hz/50 Hz or less), and for example, the first/second maximum output frequencies may be set to 60 Hz/50 Hz corresponding to the specifications of the motor device.

[Overall configuration of engine-driven generator]
1 and 2, reference numeral 1 denotes an engine-driven generator of the present invention. This engine-driven generator 1 contains an engine 3 and a generator body driven by the engine 3 in a soundproof box 8. 4. It is equipped with a configuration accommodating necessary devices such as an output line 61 for taking out the power generated by the generator main body 4 and an inverter 2 for changing the frequency of the power.

The engine-driven generator 1 also includes a control panel 7 equipped with switches and gauges for controlling the operations of the engine 3, the generator body 4, the inverter 2, etc. A three-phase output terminal block 62 to which a motor device M driven by power supply is connected is provided at a position that can be operated from the outside of the soundproof box 8 described above.

[Generator body]
The generator body 4, which is one of the main components of the engine-driven generator 1, can be of various known types. A self-excited three-phase AC generator provided with an exciter 42 is used as the generator body 4 .

The generator body 4 having such an exciter 42 is provided with an automatic voltage regulator (AVR) 43, and the output voltage of the main generator 41 is detected by this automatic voltage regulator (AVR) 43. At the same time, the detected output voltage of the main generator 41 is compared with a preset reference voltage, and if there is an error between the detected output voltage of the main generator 41 and the reference voltage, the output of the main generator 41 The exciting current supplied to the exciter 42 is controlled so that the voltage matches the reference voltage.

Therefore, by changing the setting of the reference voltage used in the automatic voltage regulator (AVR) 43, the rated output voltage of the generator body 4 can be changed.

In the engine-driven generator 1 of the present invention, the automatic voltage regulator (AVR) 43 sets the above-described reference voltage, and therefore sets the rated output voltage of the generator body 4 to a predetermined first rated output voltage ( 220 V) or the second rated output voltage (200 V).

In this embodiment, external connection terminals 44 (44a to 44c) for setting the rated output voltage are provided as the rated output voltage setting means 44, and the connection state between the external connection terminals 44 (44a to 44c) can be changed. can change the rated output voltage setting.

In the illustrated example, when the common terminal 44c is connected to the first input terminal 44a in the first connection state (see FIG. 2A), the control signal from the common terminal 44c is input to the first input terminal 44a. Then, while the rated output voltage of the generator body 4 is set to 220 V, when the common terminal 44c is connected to the second connection terminal 44b in the second connection state [see FIG. is input to the second input terminal 44b to set the rated output voltage of the generator body 4 to 200V.

[Inverter]
The engine-driven generator 1 configured as described above is provided with an output line 61 for extracting electric power generated by the generator main body 4 . are connected to a three-phase output terminal block 62 to which the motor device M is connected.

This inverter 2 has a converter section (not shown) that converts the input power into direct current, and an inverter section (not shown) that converts the direct current obtained from the converter section into alternating current of a predetermined frequency and voltage. By using a known PWM (Pulse Width Modulation) method or the like, an AC output of any frequency set by the operator can be generated by operating the frequency setting means 21 such as a dial switch provided on the control panel 7. It is configured.

Here, as mentioned above, the motor device M includes one designed on the assumption that it will be driven at 60 Hz/220 V, and another that is designed on the assumption that it will be driven at 50 Hz/200 V. If 60 Hz/220 V is output to the motor device M designed on the premise of, the motor device M may be damaged.

Therefore, in the engine-driven generator 1 of the present invention, as shown in FIG. Either the maximum output frequency (58 Hz) or the second maximum output frequency (48 Hz) is selected and set, and the maximum frequency that can be output to the inverter by operating the frequency setting means 21 is set to the first frequency. It is made variable between the maximum output frequency (58 Hz) and the second maximum output frequency (48 Hz).

In this embodiment, the maximum output frequency setting means 22 is configured by the maximum output frequency setting external connection terminals 22 (22a to 22d), and the connection state of the maximum output frequency setting external connection terminals 22 (22a to 22d) By changing , the setting of the maximum output frequency can be switched between the first maximum output frequency (58 Hz) and the second maximum output frequency (48 Hz).

In the illustrated embodiment, the maximum output frequency setting external connection terminal 22 includes a common terminal 22c, a first input terminal 22a connected/disconnected with the common terminal 22c, and a second input terminal 22a connected to the output frequency setting means 21. An input terminal 22b and a third input terminal 22d are provided.

Among them, the second input terminal 22b is invalidated when the common terminal 22c and the first input terminal 22a are in the second connection state (see FIG. 2(B)). When the first input terminals 22a are in the first connection state [see FIG. It is input through the second input terminal 22b to the provided control device (not shown).

In addition, the third input terminal 22d is disabled when the common terminal 22c and the first input terminal 22a are disconnected in the first connection state (see FIG. 2A). When the first input terminals 22a are connected to each other in the second connection state (see FIG. 2B), a control signal corresponding to the operation amount of the frequency setting means 21 is output from the frequency setting means 21. It is configured to be input to a control device (not shown) provided in the inverter 2 through the third input terminal 22d.

In this way, the second input terminal 22b is activated, that is, the control device (not shown) provided in the inverter 2 receives the control signal from the frequency setting means 21 via the second input terminal 22b. In this state, the control device (not shown) sets the maximum output frequency to a first maximum output frequency (58 Hz), and within this first maximum output frequency (58 Hz), is defined by the received control signal. The inverter 2 is caused to output at a frequency corresponding to the operation amount of the frequency setting means 21 .

On the other hand, the state in which the third input terminal 22d is activated, that is, the state in which the control device (not shown) provided in the inverter 2 receives the control signal from the frequency setting means 21 through the third input terminal 22d. Then, the control device (not shown) sets the maximum output frequency to the second maximum output frequency (48 Hz), and within the range of this second maximum output frequency (48 Hz), the frequency setting specified by the received control signal The inverter 2 is caused to output at a frequency corresponding to the manipulated variable of the means 21 .

Therefore, by setting the first connection state in which the connection between the common terminal 22c and the first input terminal 22a is cut off, the maximum output frequency can be set to the first maximum output frequency (58 Hz). 22c and the first input terminal 22a are connected to each other, and by inputting the control signal (contact signal) from the common terminal 22c to the first input terminal 22a, the maximum output frequency is changed to the second maximum output frequency ( 48 Hz).

As a result, with the external connection terminal 22 for setting the maximum output frequency set to the first connection state (disconnection between 22a and 22c), the operator operates the frequency setting means 21 to set the output frequency of the inverter 2 up to the first maximum. Although it is possible to increase the output frequency (58 Hz), when the external connection terminal 22 is set to the second connection state (connected between 22a and 22c), even if the operator operates the frequency setting means 21 at the maximum amount, the inverter cannot be increased beyond the second maximum output frequency (48 Hz).

〔engine〕
The engine 3 that drives the generator body 4 described above is configured to operate at a predetermined rated rotation speed so that a predetermined frequency (50 Hz or 60 Hz) can be obtained in the generator body 4. In the configuration of the embodiment, when the rated rotation speed of the engine 3 is set to the first rated rotation speed (1800 min ^-1 ), the generator main body 4 can obtain an output with a frequency of 60 Hz, and the engine When the rated rotation speed of 3 is set to the second rated rotation speed (1500 min ^-1 ), an output with a frequency of 50 Hz can be obtained from the generator body 4 .

Therefore, when setting the maximum output frequency of the inverter 2 to the first maximum output frequency (58 Hz), the engine rated rotation speed is set to the first rated rotation speed (1800 min ^-1 ), and the inverter maximum output frequency is set to the first 2 When setting the maximum output frequency (48 Hz), it is necessary to set the engine rated rotation speed to the second rated rotation speed (1500 min ^-1 ).

In order to change the setting of the rated rotation speed as described above, the engine-driven generator 1 of the present invention is provided with a rated rotation speed changing means 56, and an operating portion of the rated rotation speed changing means 56. 57, 57' are provided on the control panel 7, and by operating the operating portions 57, 57' of the rated rotation speed changing means 56 on the control panel 7, the rated rotation speed of the engine 3 can also be changed. configured as

As shown in FIG. 6, in the configuration of this embodiment, which employs a mechanical governor for the speed control mechanism of the engine 3, the operation unit (operation knob) provided on the control panel 7 is provided with the rated rotation speed changing means 56, as shown in FIG. 57 and a mechanical link (in the example of FIG. 6, a link cable) 58 that connects the operation knob 57 and the governor lever 33 of the engine 3, so that the governor lever 33 of the engine 3 can be operated by the operation knob 57. .

In this embodiment, as shown in the enlarged view of FIG. 6, the operation knob 57 moves forward and backward between a position pushed toward the control panel 7 (idling position) and a position pulled out (operating position). In addition, by rotating the operation knob 57 counterclockwise in the pulled out position (operating position), the rotation speed of the engine is high and it can be rotated clockwise. The tilting position of the governor lever 33 can be adjusted so that the rotation speed of the engine becomes low at .

Therefore, after starting the engine with the operation knob 57 pushed in (idling position), the operator can pull out the operation knob 57 to increase the engine rotation speed to the rated rotation speed. In this state, operate the operation knob 57 while looking at the engine tachometer or the like provided on the control panel 7, and turn the operation knob 57 to set the maximum output frequency of the inverter 2 to the first maximum output frequency (58 Hz). is rotated in the counterclockwise direction so that the rated rotation speed of the engine becomes (closer to) the first rotation speed (high speed: 1800 min ^-1 ), and the setting of the maximum output frequency of the inverter 2 is changed to the second maximum output frequency In the case of (48 Hz), the operation knob 57 can be rotated clockwise to change the rated rotation speed of the engine to (approach) the second rotation speed (low speed: 1500 min ^-1 ).

[Interlocking operation means (changeover switch)]
The control panel 7 of the engine-driven generator 1 configured as described above includes rated output voltage setting means 44 provided in the automatic voltage regulator (AVR) 43 and maximum output frequency setting means provided in the inverter 2. 22 to set the rated output voltage to the first rated output voltage (220 V), set the maximum output frequency to the first maximum output frequency (58 Hz), and set the rated output voltage to the second rated output voltage. Interlocking operation means 5 is provided for setting the maximum output frequency to a second maximum output frequency (48 Hz) when the output voltage (200 V) is set.

In this embodiment, as shown in FIGS. 1 to 5, 7 and 8, this interlocking operation means is constituted by a changeover switch 5. FIG.

In the example shown in FIG. 2, the changeover switch communicates the contacts 52c and 52a when the contacts 51c and 51b are communicated, and communicates the contacts 52c and 52b when the contacts 51c and 51a are communicated. A double-pole double-throw switch is used.

The contact 51a of the selector switch 5 is connected to the first input terminal 22a of the external connection terminal 22 for setting the maximum output frequency provided on the inverter 2, and the contact 51c is connected to the common terminal 22c of the external connection terminal 22 for setting the maximum output frequency. While connecting each (nothing is connected to the contact 51b), the first input terminal 44a of the external connection terminal 44 for setting the rated output voltage provided in the automatic voltage regulator (AVR) is connected to the contact 52a, and the rated output voltage is connected to the contact 52b. The second input terminal 44b of the output voltage setting external connection terminal 44 is connected, and the common terminal 44c of the rated output voltage setting external connection terminal 44 is connected to the contact 52c.

As a result, when the selector switch 5 is switched to the first switching position [see FIG. The disconnected first connection state is established, the first maximum output frequency (58 Hz) is set to the maximum output frequency, and the external connection terminal 44 for setting the rated output voltage of the automatic voltage regulator (AVR) 43 is connected to the common terminal 44c. and the first input terminal 44a are connected to the first connection state, and the first rated output voltage (220V) is set as the rated output voltage.

On the other hand, when the selector switch 5 is set to the second switching position (see FIG. 2(B)), the external connection terminal 22 for setting the maximum output frequency of the inverter 2 is connected to the common terminal 22c and the first input terminal 22a. A connection state is established, the second maximum output frequency (48 Hz) is set to the maximum output frequency, and the external connection terminal 44 for setting the rated output voltage of the automatic voltage regulator (AVR) 43 is connected to the common terminal 44c and the second input terminal. 44b is connected to the second connection state, and the second rated output voltage (200 V) is set to the rated output voltage.

[Modification 1]
In the embodiment described above, the engine 3 has been described as having a structure equipped with a mechanical governor as a speed control mechanism. As such, it may be an electronically controlled engine with an engine control module (ECM) 31 .

When adopting such an electronically controlled engine 3, the engine control module (ECM) 31 sets the rated rotational speed of the engine 3 to a predetermined first rotational speed (1800 min ^-1 ) or a predetermined first rotational speed. A rated rotation speed setting means 32 for setting one of two rotation speeds (1500 min ^-1 ) may be provided.

Although the rated rotation speed setting means 32 may be independently operated, the interlocking operation means (changeover switch) 5 described above enables the maximum output frequency setting means 22 provided in the inverter 2 and the automatic voltage adjustment means 22 to be set. It is preferable to operate in conjunction with the rated output voltage setting means 44 provided in the device (AVR).

In this embodiment, the rated rotation speed setting means 32 provided in the engine control module (ECM) 31 is configured by the rated rotation speed setting external connection terminals 32 (32a to 32c), and the common terminal 32c of the external connection terminal 32 is connected to the first input terminal 32a, the first rated rotation speed (1800 min ^-1 ) is set as the rated rotation speed in the first connection state, and the common terminal 32c is connected to the second input terminal 32b. The second rated rotation speed (1500 min ^-1 ) is set as the rated rotation speed in the connected state.

As shown in FIG. 7, changing the connection state of the external connection terminals 32 (32a to 32c) for setting the rated rotation speed can be done by using the changeover switch for setting the maximum output frequency and setting the rated output voltage. (Interlocking operation means) A switch 57' is provided separately from 5, and this switch 57' and the rated rotation speed setting external connection terminals 32 (32a to 32c) constitute rated rotation speed changing means 56. ' is an operation unit provided on the control panel 7 of the rated rotation speed changing means 56. By operating the switch 57', the rated rotation of the engine 3 is controlled independently of the setting of the maximum output frequency and the setting of the rated output voltage. The configuration may be such that the speed setting can be changed.

Preferably, as shown in FIG. 3, the changeover switch 5 for setting the maximum output frequency and the rated output voltage described above is provided with contacts 51a to 51c and 52a to 52c, as well as contacts 53a to 53c. The first input terminal 32a of the external connection terminal 32 for setting the rated rotation speed provided in the engine control module (ECM) 31 is connected to the contact 53a, and the contact 53b is connected to the input terminal 32a for setting the rated rotation speed. The second input terminal 32b of the external connection terminal 32 is connected, and the common terminal 32c of the external connection terminal 32 for setting the rated rotational speed is connected to the contact 53c.

As a result, when the selector switch 5 is in the first switching position (see FIG. 3), the external connection terminal 32 for setting the rated rotational speed of the engine control module (ECM) 31 is connected to the common terminal 32c and the first input terminal 32a. The first connection state is established, and the first rated rotation speed (high speed: 1800 min ^-1 ) is set as the rated rotation speed of the engine 3 .

On the other hand, when the selector switch 5 is set to the second switching position (not shown), the external connection terminal 32 for setting the rated rotation speed of the engine control module (ECM) 31 is connected to the common terminal 32c and the second input terminal 32b. The second connection state is entered, and the second rated speed (1500 min ^-1 ) is set as the rated speed of the engine.

As a result, by operating the selector switch 5, the maximum output frequency of the inverter 2, the rated output voltage of the automatic voltage regulator (AVR) 43, and the rated rotational speed of the engine control module (ECM) 31 are set. can be reliably changed simultaneously and in the correct combination.

Thus, in addition to the setting of the maximum output frequency of the inverter 2 and the setting of the rated output voltage of the automatic voltage regulator (AVR) 43, the setting of the rated speed of the engine control module (ECM) 31 can also be performed by a single selector switch. 5, unlike the examples shown in FIGS. 6 and 7, as shown in FIG. There is no need to provide switches for

[Modification 2]
In the engine-driven generator 1 described with reference to FIGS. 2 and 3, the maximum output frequency of the inverter 2 is set to the first maximum output frequency (58 Hz) or the second maximum output frequency by operating the changeover switch 5 as interlocking operation means. Enabled to switch to frequency (48Hz).

On the other hand, in the embodiment shown in FIG. The setting of the base frequency is also different in that it can be switched to a predetermined first base frequency (60 Hz as an example) or a second base frequency (50 Hz as an example).

Here, there are a "base frequency" and a "base frequency voltage" as parameters that serve as references for operating a three-phase induction motor.

The "base frequency" and "base frequency voltage" are the maximum frequency and voltage at which a three-phase induction motor can be operated continuously at the rated torque. Correspondingly, the base frequency/base frequency voltage is designed to be 50Hz/200V or 60Hz/220V.

When the output frequency of the inverter 2 is changed to control the rotational speed of the motor device (three-phase induction motor) M, the ratio of voltage (V) to frequency (f) remains constant (V/ By performing so-called "V/f constant control" in which f=constant), the motor device M can be operated at a constant torque even when the rotational speed changes.

In such a "constant V/f control", the V/f pattern for the motor device M with a base frequency and base frequency voltage of 60 Hz/220 V is shown by the solid line in FIG. An example of the V/f pattern for the motor device M with a base frequency and base frequency voltage of 50 Hz/200 V is shown by the dashed line in FIG. The V/f pattern to be applied to obtain torque operation varies.

Here, in the V/f pattern with the base frequency/base frequency voltage of 60 Hz/220 V (see the solid line graph in FIG. 9 as an example), the V/f pattern with the base frequency/base frequency voltage of 50 Hz/200 V (as an example (see the dashed line graph in Fig. 9), the voltage at the same frequency is lower, so if the motor device M with 50Hz/200V specifications is driven with a V/f pattern of 60Hz/220V that does not correspond to the base frequency, , the output torque of the motor device M decreases due to insufficient voltage.

As a result, overcurrent occurs in the inverter 2 of the engine-driven generator 1 even when the motor device M is driven at less than the rated output, and the protection function of the inverter 2 interrupts the output called "overcurrent trip". may occur, and this may result in the inability to work.

In particular, when the motor device M has a low power factor, even if the output is the same, it consumes a large amount of current, so overcurrent is likely to occur, and the output cutoff due to the above-mentioned "overcurrent trip" is even more likely to occur. become a thing.

Therefore, when changing the setting of the output frequency of the inverter 2 according to the specifications of the connected motor device M, not only the maximum output frequency described above but also the setting of the base frequency is changed accordingly. Therefore, it is desirable that the motor device M can be operated at a constant torque even if the rotational speed of the motor device M is variable.

In the engine-driven generator 1 of the present embodiment, the maximum output frequency setting means 22 provided in the inverter 2 is configured to be able to simultaneously switch the setting of the maximum output frequency and the setting of the base frequency. , when the maximum output frequency is set to the first maximum output frequency (58 Hz), the base frequency of the inverter is set to the first base frequency (60 Hz) at the same time, and the maximum output frequency is set to the second maximum output frequency ( 48 Hz), a base frequency setting function is added to simultaneously set the base frequency to the second base frequency (50 Hz).

Specifically, as shown in FIG. 4, the maximum output frequency setting means (external connection terminal for maximum output frequency setting) 22 provided in the inverter 2 is further provided with a fourth input terminal 22e. is connected in parallel with the first input terminal 22a, and the common terminal 22c is connected to the first input terminal 22a. It is configured to be input also to the fourth input terminal.

As a result, when there is no control signal input to the fourth input terminal 22e, the control device (not shown) provided in the inverter 2 sets the base frequency to the first base frequency (60 Hz) and the fourth input terminal 22e. By configuring the base frequency to be the second base frequency (50 Hz) when the control signal is input to the terminal 22e, the setting of the maximum output frequency and the setting of the base frequency can be switched at the same time. made it

In the embodiment shown in FIG. 4, the maximum output frequency setting means 22 provided in the inverter 2 of the engine-driven generator 1 described with reference to FIG. The configuration is such that the output frequency, base frequency, rated output voltage, and engine rotation speed are all switched simultaneously by operating a single selector switch 5 .

On the other hand, the maximum output frequency setting means 22 provided in the inverter 2 of the engine-driven generator 1 explained with reference to FIG. As a configuration with a base frequency setting function added, the maximum output frequency, base frequency, and rated output voltage can be switched at the same time. A switch 57' (see FIG. 7) may be provided for switching.

Also, when changing the setting of the base frequency, other parameters that are desirable to be changed at the same time as the base frequency (for example, torque boost amount, acceleration time, deceleration time, etc.) may be changed at the same time.

1 engine-driven generator 2 inverter 21 frequency setting means (dial switch)
22 maximum output frequency setting means (external connection terminal for maximum output frequency setting)
22a first input terminal 22b second input terminal 22c common terminal 22d third input terminal 22e fourth input terminal 3 engine 31 engine control module (ECM)
32 rated rotation speed setting means (external connection terminal for setting rated rotation speed)
32a First input terminal 32b Second input terminal 32c Common terminal 33 Governor lever 4 Generator body 41 Main generator 42 Exciter 43 Automatic voltage regulator (AVR)
44 rated output voltage setting means (external connection terminal for setting rated output voltage)
44a first input terminal 44b second input terminal 44c common terminal 5 interlocking operation means (switch)
51a to 51c, 52a to 52c, 53a to 53c Contact 56 Rated rotation speed changing means 57 Operation part (operation knob)
57' operation unit (switch)
58 link 61 output line 62 three-phase output terminal block 63 breaker 65 starter switch 7 control panel 8 soundproof box 300 engine-driven generator 302 inverter 303 engine 304 generator body 307 control panel 308 soundproof box 321 frequency setting means (dial switch)
343 Automatic Voltage Regulator (AVR)
351 (351a, 351b) Three-phase output line 361 Three-phase output terminal block

Claims (7)

a generator main body, an engine that drives the generator main body, a three-phase output terminal block that outputs the power generated by the generator main body, a three-phase output terminal block provided between the generator main body and the three-phase output terminal block, the generator In an engine-driven generator equipped with an inverter that converts the frequency of the three-phase AC power output by the main body and outputs it to the three-phase output terminal block, and an automatic voltage regulator that controls the output voltage of the generator main body,
The inverter is provided with maximum output frequency setting means for setting the maximum output frequency of the inverter to a predetermined first maximum output frequency or a predetermined second maximum output frequency,
The automatic voltage regulator has a rated output voltage setting that sets the rated output voltage of the generator body controlled by the automatic voltage regulator to a predetermined first rated output voltage or a predetermined second rated output voltage. provide means,
When the maximum output frequency setting means and the rated output voltage setting means are operated in conjunction to set the maximum output frequency to the first maximum output frequency, the rated output voltage is set to the first frequency at the same time. The interlocking operation means for setting the rated output voltage to the rated output voltage and setting the rated output voltage to the second rated output voltage at the same time when the setting of the maximum output frequency is set to the second maximum output frequency, the engine driving An engine-driven generator provided operably on a control panel of the engine-driven generator. In the inverter, as the maximum output frequency setting means, when a predetermined first connection state is established, the maximum output frequency is set to the first maximum output frequency, and when a predetermined second connection state is established, the maximum output frequency is set. providing an external connection terminal for setting the maximum output frequency that makes the frequency equal to the second maximum output frequency;
The automatic voltage regulator, as the rated output voltage setting means, sets the rated output voltage to the first rated output voltage in a predetermined first connection state, and sets the rated output voltage to the first rated output voltage in a predetermined second connection state. providing an external connection terminal for setting the rated output voltage for setting the rated output voltage to the second rated output voltage;
The interlocking operation means,
a contact connected to each of the external connection terminal for setting the maximum output frequency and the external connection terminal for setting the rated output voltage;
a first switching position for connecting the contacts so that both the external connection terminal for setting the maximum output frequency and the external connection terminal for setting the rated output voltage are in the first connection state;
wherein the external connection terminal for setting the maximum output frequency and the external connection terminal for setting the rated output voltage are both changeover switches having a second switching position for connecting between the contacts so as to establish the second connection state. 2. An engine-driven generator according to claim 1. on the control panel of the engine-driven generator,
3. The engine-driven power generator according to claim 1, further comprising an operation unit for rated rotation speed changing means for changing the rated rotation speed of the engine to the first rated rotation speed or the second rated rotation speed. machine. The engine is an electronically controlled engine equipped with an engine control module,
The engine control module is provided with rated rotation speed setting means for switching the setting of the rated rotation speed of the engine to a predetermined first rated rotation speed or a predetermined second rated rotation speed,
The interlocking operation means interlocks the rated rotation speed setting means together with the maximum output frequency setting means and the rated output voltage setting means to set the maximum output frequency to the first maximum output frequency and the When setting the rated output voltage to the first rated output voltage, simultaneously setting the rated rotation speed to the first rated rotation speed,
2. When setting said maximum output frequency to said second maximum output frequency and said rated output voltage to said second rated output voltage, said rated speed is set to said second rated speed at the same time. 2. The engine-driven generator according to 1. The engine is an electronically controlled engine equipped with an engine control module,
In the engine control module, the rated rotation speed is set to a predetermined first rated rotation speed when a predetermined first connection state is established, and the rated rotation speed is set to a predetermined first rated rotation speed when a predetermined second connection state is established. 2 Provide an external connection terminal for setting the rated rotation speed,
The changeover switch is further provided with a contact connected to the external connection terminal for setting the rated rotation speed,
When the selector switch is set to the first switching position, the external connection terminal for setting the rated rotation speed is set to the first connection state, and when the selector switch is set to the second switching position, the rated rotation speed is set. 3. The engine-driven generator according to claim 2, wherein the contacts are connected so that the external connection terminal for the generator is in the second connection state. When the maximum output frequency is set to the first maximum output frequency in the maximum output frequency setting means provided in the inverter, at the same time, the base frequency of the inverter is set to a predetermined first base frequency, and 2. A base frequency setting function is added for simultaneously setting the base frequency of said inverter to a predetermined second base frequency when setting the maximum output frequency to said second maximum output frequency. An engine-driven generator as described. When the maximum output frequency setting external connection terminal is in the first connection state, the maximum output frequency is set to the first maximum output frequency, the base frequency of the inverter is set to the predetermined first base frequency, and the first base frequency is set to the first base frequency. 3. The engine-driven generator according to claim 2, wherein said maximum output frequency is set to said second maximum output frequency and the base frequency of said inverter is set to a predetermined second base frequency when in the two-connection state.

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