JPH075889U - Control circuit of DC feeding voltage compensator - Google Patents

Abstract

(57) [Summary] [Purpose] Compensate the feeding voltage without feedback delay. [Configuration] Comparator 7 is a DC voltage detector DCCT ₁
The load current detected in step S4 is compared with the rated current of the setter 4, and when the load current exceeds the rated current, the analog switch 8 is turned on to input the set output voltage of the setter 3 to the integrating amplifier 11, The thyristor rectifier 2 is phase-controlled via the control circuits 12 to 15 to output a voltage corresponding to the set output voltage to compensate the feeding voltage from the silicon rectifier 1. The load current during operation of the thyristor rectifier 2 is CT ₁ ,
Detected by the circuit of CT ₂ and rectifier 16, comparator 17
As a result, when the load current exceeds 300% of the rated value, a stop command for the thyristor rectifier 2 is output to stop the voltage compensation.
However, the compensation of the feeding voltage is 100 to 3 when the load current is rated.
In the range of 00%. Since this circuit does not have a feedback circuit using a DC voltage detector having a slow response, no response delay occurs.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a control circuit of a DC feeder voltage compensator (thyristor rectifier) used in series with a silicon rectifier that outputs a feeder voltage in a DC electric railway substation and compensating so as to keep the feeder voltage constant. .

[0002]

[Prior art]

 FIG. 7 shows a control circuit of a thyristor rectifier conventionally used as a DC feeding voltage compensator (DCVR). 1 is a silicon rectifier that rectifies the output of the secondary side S of the three-phase transformer TR and outputs it to the electric wires P and N. 2 is a rectifier of the output of the tertiary side T of the three-phase transformer TR and decreases the output voltage of the silicon rectifier 1. Is a silicon rectifier connected in series with the silicon rectifier 1 for compensating for the above, and D is a bypass diode of the silicon rectifier 2.

Reference numerals 3 to 15 are control circuits of the silicon rectifier 2. The voltage control amplifier 11 ′ amplifies the deviation between the set output voltage of the voltage setting device 3 and the detected voltage from the direct current voltage detector 9, and the phase control circuit. The phase pulse is generated by 12 and the thyristor rectifier 2 is phase-controlled via the gate signal generating circuit 13, the pulse transformer 14, and the gate circuit 15.

However, as shown in FIG. 8, for example, the DCVR output voltage becomes the maximum at the rated current Is or more, the feeding voltage V is controlled to be constant in the range of 0 to the rated current, and the silicon rectifier is set at the rated current or more. It has the property of decreasing according to the regulation of.

This constant control of the feeding voltage makes it possible to compensate for the decrease in the input voltage of the vehicle and lengthen the interval between the substations.

Further, the silicon rectifier (DCVR) is connected in series with the silicon rectifier and is always energized, or in order to downsize the device, as shown in FIG. 9, the DCVR receives a load current larger than the rated current. A method of operating it when it is turned on is considered.

[0007]

[Problems to be solved by the device]

 The above-mentioned conventional feeding voltage control device uses a DC voltage detector in the control voltage feedback system, and the response of this DC voltage detector is very slow at 0.3 seconds. Therefore, when a powered vehicle enters the feeder section of the substation, or when the powered vehicle or coasting vehicle raises the notch, the output of the DCVR is greatly reduced due to the slow response of feedback, and the output voltage is reduced. It takes a long time to return to the original state.

The present invention has been made in view of the above problems in the related art, and an object of the present invention is to provide a direct current feeder capable of compensating for a direct current voltage with no feedback delay and at low cost. It is to provide a control circuit of a voltage compensation device.

[0009]

[Means for Solving the Problems]

 In order to achieve the above object, the control circuit of the DC feed voltage compensator according to the present invention comprises: (1) a first comparator for detecting that the detected load current exceeds a set current and turning on a switch; An integral amplifier that amplifies the set output voltage that is input when the switch is turned on and outputs it to the phase control circuit of the thyristor rectifier (feeding voltage compensator), and detects that the load current has exceeded about 2 to 3 times the rated value. And a second comparator that outputs a stop command for the thyristor rectifier.

(2) A first comparator that detects that the detected load current is equal to or greater than a set current, an integral amplifier that integrates and amplifies the output of this comparator, and outputs the integrated output to the phase control circuit of the thyristor rectifier, It is characterized by comprising a second comparator which detects that the load current has become about 2 to 3 times the rated value or more and outputs a stop command for the thyristor rectifier.

Alternatively, (3) a high gain amplifier that amplifies the difference between the detected load current and the set current, a voltage divider that divides the output of the high gain amplifier and outputs a small voltage, the detected load current and the set current. Similarly, an amplifier that amplifies the difference between the set current and an integrating amplifier that amplifies the output of this amplifier and the small voltage from the voltage divider and outputs it to the phase control circuit of the thyristor rectifier, and the load current is rated. It is characterized by being provided with a second comparator which outputs a command to stop the thyristor rectifier when it detects that it is about 2 to 3 times or more.

[0012]

[Action]

 Regarding the above (1), when the load current exceeds the set current, the first comparator turns on the switch and inputs the set output voltage to the integrating amplifier. This integrating amplifier integrates and amplifies this set output voltage and outputs it to the phase control circuit. Therefore, when the load current exceeds the set current, the thyristor rectifier is phase-controlled and outputs a voltage equivalent to the set output voltage, compensating for the feed voltage dropped by the load current.

When the load current exceeds the setting of the second comparator set to 2 to 3 times the rated value, a stop command is output from this comparator to stop the output of the thyristor rectifier. Therefore, the feeding voltage is compensated within a range in which the load current is 2 to 3 times the rated current from the set current.

Regarding the above (2), when the load current exceeds the set current, the first comparator outputs. The integrating amplifier with limiter amplifies this output and outputs a substantially constant voltage to the phase control circuit. Therefore, the thyristor rectifier is phase-controlled and compensates for the voltage when the load current exceeds the set current. When the load current exceeds the set value of the second comparator, this comparator issues a command to stop the thyristor rectifier.

Regarding the above (3), when the load current exceeds the set current, a substantially constant voltage is output from the high gain amplifier, and this voltage is divided by the voltage divider. At the same time, it is output from the amplifier that amplifies the difference between the load current and the set current. The small voltage from the voltage divider is added to the output of the amplifier, amplified by the integral amplifier with limiter, and output to the phase control circuit.Therefore, the thyristor rectifier compensates the phase-controlled voltage when the load current exceeds the rated value. To do. When the load current exceeds the setting of the comparator, this comparator issues a command to stop the thyristor rectifier.

[0016]

【Example】

 Embodiment 1 An embodiment of the present invention will be described with reference to the drawings. In the drawings of each embodiment, the same components as those shown in FIG. 7 of the related art are designated by the same reference numerals, and the duplicated description thereof will be omitted.

In FIG. 1, 3 is a DCVR output voltage setting device, 4 is a rated current setting device, and DCCT. ₁ Is a direct current detector for detecting load current, 7 is a direct current detector DCCT₁A comparator that compares the detected current from the controller with the rated current from the setting device 4 and outputs it. 8 is an analog switch that turns on the output of the comparator 7 and outputs the set voltage from the setting device 3 to the integrating amplifier 11 Is a phase control circuit connected to the integrating amplifier 11.

Reference numeral 16 is a rectifier that rectifies the outputs of the current transformers CT ₁ and CT ₂ that detect the input current of the thyristor rectifier 2 and outputs an input current value. 17 is set to this detected input current and 300% of the rating. The comparator outputs a stop command for the thyristor rectifier 2 when the input current (= load current) exceeds 300% of the rated value in comparison with the set current. Others are the same as in FIG. 7 of the related art.

Next, the operation of this circuit will be described with reference to FIG. When the load current I is equal to or less than the rated current Is, the comparator 7 does not output and the analog switch 8 is in the OFF state. Therefore, the integrating amplifier 11 has no input from the voltage setting device 3 and the thyristor rectifier (DCVR) 2 does not output.

When the load current I exceeds the rated current Is, the comparator 7 outputs and the analog switch 8 turns on, the set output voltage from the voltage setter 3 is input to the integrating amplifier 11, and the phase is integrated and amplified to obtain the phase. The phase pulse is converted by the control circuit 12 and the phase of the thyristor rectifier 2 is controlled via the circuits 13 to 15.

Although the voltage feedback circuit is not used in this control circuit, if the DCVR currently made exceeds the rated current, it will fall out of the range of the rated control. Therefore, the thyristor rectifier is used above the rated current. As long as you are there, there is no problem. As shown in FIG. 2, the thyristor rectifier 2 then outputs a voltage (200 V) set above the rated current I _S to compensate the feeding voltage.

When the load current exceeds 300% of the rating, the comparator 17 outputs and a thyristor rectifier stop command is output. Therefore, the output voltage of the thyristor rectifier 2 becomes zero, and the feeding voltage becomes the output voltage of the silicon rectifier 1 as shown in FIG. In this case, the load current I flows through the circuit of the bypass diode D.

According to this embodiment, since the DC voltage detector for voltage feedback is not used, the control response is not delayed, the number of parts is reduced, and the device can be made small and inexpensive.

Embodiment 2 Referring to FIG. 3, a is a shunt circuit for shunting the feeding current I, and 9 is a detection load current from the DC voltage detector DCCT ₂ provided in the shunt circuit a and a rated current setting device 4 A high-gain amplifier (comparator) that amplifies the difference from the set rated current, 11 ₁ is an integral amplifier with a limiter that is connected to the high-gain amplifier 9 via a backflow prevention diode D ₂ and outputs to the phase control circuit 12. Other configurations are the same as those in the first embodiment.

With the configuration as described above, when the detected load current from the DC current detector DCCT ₂ becomes larger than the rated current, the voltage control is set to the integrating amp with limiter 11 ₁ via the diode D _2. This setting is integrated and amplified, and the output is controlled to be constant and input to the phase circuit 12 to be converted into a phase pulse to control the phase of the thyristor rectifier through the circuits 13 to 15. Compensate the feeding voltage as shown in.

In this case, voltage feedback is not used, but there is no problem for the same reason as described in the first embodiment.

According to this embodiment, since the DC current detector DCCT ₂ is provided in the shunt circuit a to detect the load current, a small capacity DC current detector can be used. Since the thyristor rectifier is not required to be set to 100% accuracy, the shunt conductor and the DC current detector are not required to be accurate.

Embodiment 3 Referring to FIG. 4, 9 ₁ is an amplifier for amplifying the difference between the current value from the rectifier 16 and the current setting value of the current setting device 4, 10 is the DC voltage detector DCCT ₁ and the current setting device 4 ₁ High-gain amplifier with limiter that amplifies the difference from the current setting value of 11; 11 ₁ is a limiter that amplifies the sum of the output of the amplifier 9 ₁ and the current signal input from the amplifier 10 via the reverse diode D ₃ and the voltage divider VR. The integrated amplifier, 12 is a phase control circuit connected to the amplifier 11 ₁ through a diode D ₄ . The other circuits are the same as those of the first embodiment.

Next, the operation of this circuit will be described with reference to FIGS. The difference between the detected input current (= load current) from the rectifier 5 and the rated current from the setter 4 is increased by the amplifier 9 ₁ . The voltage setting is output from the amplifier 9 _{1 as} shown in FIG.

On the other hand, the difference between the load current detected by the DC current detector DCCT ₁ and the rated current from the setting device 4 ₁ is amplified by the high gain amplifier 10 with limiter, and its output is divided by the voltage divider VR, The small voltage that has been compressed is added to the voltage setting from the amplifier 9 ₁ and amplified by the integrating amplifier with limiter 11 ₁ .

The voltage setting as shown in FIG. 5B is output from the integrating amplifier with limiter 11 ₁ to the phase control circuit 12 to control the phase of the thyristor rectifier 2 via the circuits 13 to 15. Silicon Therefore the load current I of the amplifier 10 or 1 1 ₂ when the load current I increases the output voltage of the silicon rectifier 2 exceeds the rated current I _S exceeds a certain value limiter as shown in FIG. 6 moves The output voltage of the rectifier 2 becomes constant, and the feeding voltage has a voltage characteristic parallel to the slope of regulation of the silicon rectifier 1.

When the load current I exceeds 300% of the rated value, the comparator 17 operates to output a stop command for the thyristor rectifier 2, so that the DCVR output voltage becomes zero. In this case, no voltage feedback is used, but there is no problem for the same reason as described in the first embodiment.

According to this embodiment, since the DC voltage detector for voltage feedback is not used, the same effect as that of the first embodiment can be obtained.

[0034]

[Effect of device]

 Since the present invention is configured as described above, it has the following effects.

(1) Since the thyristor rectifier is controlled without using the DC voltage detector for voltage feedback, it is possible to compensate the feeding voltage without a control response delay by the DC voltage detector.

(2) Since the DC voltage detector is not used, the number of parts can be reduced, the device size can be reduced, and the cost can be reduced.

(3) The thyristor rectifier operates only when a load larger than the rated current is taken into the feeding section, and current does not always flow unlike the conventional thyristor rectifier, so that it can be miniaturized.

(4) According to the fourth aspect, since the direct current detector for detecting the feeding current is provided in the shunt conductor, the shunt conductor can have a small capacity and the setting accuracy of the thyristor rectifier is rough. Therefore, inexpensive shunt conductors and DC current detectors can be used.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing a first embodiment.

FIG. 2 is an output voltage characteristic diagram of Examples 1 and 2.

FIG. 3 is a block circuit diagram showing a second embodiment.

FIG. 4 is a block circuit diagram showing a third embodiment.

5A and 5B are voltage setting characteristic diagrams in the third embodiment.

FIG. 6 is an output voltage characteristic diagram of the third embodiment.

FIG. 7 is a block circuit diagram showing an embodiment.

FIG. 8 is an output voltage characteristic diagram of a conventional example.

FIG. 9 is a currently considered output voltage characteristic diagram.

[Explanation of symbols]

1 ... Silicon rectifier 2 ... Thyristor rectifier (DCVR) 3 ... Output voltage setting device 4, 4 ₁ ... Rated current setting device 7 ... Comparator 8 ... Analog switch 9 ... Comparator (high gain amplifier) 9 ₁ ... Amplifier 10 ... High gain amplifier with limiter 11 ... Integrating amplifier 11 ₁ ... Integrating amplifier with limiter 11 '... Voltage control amplifier (PI amplifier) 12 ... Phase control circuit 13 ... Gate oscillating circuit 14 ... Pulse transformer 15 ... Gate circuit 16 ... Rectifier 17 ... 300% set comparator

Claims (5)

[Scope of utility model registration request] 1. A detection rectified current is set in a thyristor rectifier in which a bypass diode is connected in series with a silicon rectifier that outputs a feeding voltage and the thyristor rectifier is phase-controlled to compensate the feeding voltage. A first comparator that turns on the switch by detecting that the current is exceeded, an integrating amplifier that amplifies the set output voltage by turning on the switch and outputs the amplified output voltage to the phase control circuit of the thyristor rectifier, and a rated current of about 2 to A control circuit for a DC feed voltage compensator, comprising: a second comparator that outputs a stop command for the thyristor rectifier when the detected load current is set to triple and exceeds the set value. 2. A thyristor rectifier in which a bypass diode is connected in series with a silicon rectifier that outputs a feeding voltage is connected, and the DC feeding voltage is compensated by controlling the phase of the thyristor rectifier. A first comparator that detects that the current exceeds the set current, an integral amplifier with a limiter that integrates and amplifies the output of this comparator and outputs it to the phase control circuit of the thyristor rectifier, and sets it to approximately 2 to 3 times the rated current. A control circuit for a DC feed voltage compensator, comprising: a second comparator that outputs a stop command for the thyristor when the detected load current exceeds its set value. 3. A detection load current and a setting in which a thyristor rectifier having a bypass diode connected in series with a silicon rectifier that outputs a feeding voltage is connected, and the feeding voltage is compensated by controlling the phase of the thyristor rectifier. A high-gain amplifier that amplifies the difference with the current, a voltage divider that divides the output of this high-gain amplifier and outputs a small voltage, and an amplifier that amplifies the difference between the detected load current and the set current that is the same as the set current. Integrating amplifier with limiter that adds and amplifies the output of this amplifier and the small voltage from the voltage divider to the phase control circuit of the thyristor rectifier, and the load current that is set to about 2 to 3 times the rated current. Of the thyristor rectifier, a comparator for outputting a stop command for the thyristor rectifier, and Control circuit. 4. The detected load current is detected by a direct current detector provided in a shunt circuit for the load current and provided in the shunt circuit. The DC feeding voltage compensating device according to. 5. The detected load current input to the comparator that outputs a stop command for the thyristor rectifier is detected at the input side of the thyristor rectifier. DC feeding voltage compensator.