JP2000117146A - Spark detector of electric precipitator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To certainly detect the spark generation of an electric precipitator. SOLUTION: A spark detector is equipped with a charge voltage detection means 30 detecting the value of charge voltage applied across a dust collection electrode 11 and a discharge electrode 12, a detection waveform modifying circuit 34 and a charge voltage lowering detection threshold value setting device 36 setting a charge voltage lowering threshold value 62 becoming a judge standard of spark generation so as to change corresponding to the carge voltage measured value 60 detected by the charge voltage detection means 30 and a charge voltage lowering judge device 38 judging the presence of spark generation by comparing the charge voltage measured value 60 detected by the charge voltage detection means 30 and the charge voltage lowering threshold value 62 set by the detection waveform modifying circuit 34 and the charge voltage lowering detection threshold value setting device 36. By this constitution, spark discharge can be certainly detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spark detector of an electric dust collector for collecting dust in the air, and more particularly to a spark detector of the electric dust collector for preventing erroneous determination of the spark detector. Related to the device.

[0002]

2. Description of the Related Art Generally, it is advantageous in terms of the performance of an electrostatic precipitator to operate at a higher charging voltage. Therefore, usually equipped with a constant current control of the discharge current or a control device that uses a combination of the constant current control and the constant voltage control method of the load voltage, and when there is no spark, the output upper limit value set by the setter of each control. You are driving. Also, with the aim of preventing the transition from the corona discharge zone to the arc / glow discharge zone, automatic control is performed at the time of spark generation, which is generally called `` spark tracking control '', `` spark frequency control '' or `` spark integration control ''. It controls the charging voltage and discharge current of the electrostatic precipitator.

The operation of the conventional spark detection circuit will be described below. When a spark occurs, a phenomenon occurs in which the charging voltage decreases, and the output side of the power supply device is short-circuited, so that the discharge current increases. The spark detection is performed only when the discharge current is equal to or higher than a predetermined discharge current excess detection threshold, and when the AND condition that the charging voltage rapidly decreases to a predetermined charging voltage lowering detection threshold or lower is satisfied. Judgment was made and the automatic control at the time of spark generation described above was performed.

[0004] A signal from the spark detection circuit controls the power supply of the electric precipitator by using the following two operation modes depending on the situation. Note that the threshold value for determining spark detection is determined in the case of the continuous charging method, which is one of the operation modes of the power supply device, and in the case of another method of performing charging / pausing cyclically.
In the case of the intermittent charging method which is one of the two operation modes, the detection operation is performed by setting the same threshold value.

[0005]

However, in the case of the intermittent charging method, the charging voltage drops when charging is stopped and the rush charging current flows when the dust collector is recharged. Therefore, if the threshold value in the continuous charging method is maintained, a malfunction of spark detection has occurred. Conventionally, in order to prevent the malfunction, the set value of the discharge current excess threshold value is increased to prevent the malfunction. As a result, if sparks with a low current value occur frequently, automatic control at the time of spark does not function because it cannot be detected as a spark, which helps to reduce the charging voltage and ultimately protects the power supply unit and the electric dust collector The "low voltage detection device", which is a function provided in the system, operates to reach an event that trips the power supply device.

On the other hand, when the set threshold value of the charging voltage is lowered, the control is automatically performed even when an arc which does not need to be detected and a self-extinguishing spark which does not shift to glow discharge. As a result, the non-charging time increases due to the increase in the charging temporary suspension time, and the performance of the electrostatic precipitator deteriorates. 3 (A), (B), (C),
(D) shows the signal processing function of the conventional spark discharge prevention circuit. FIG. 3A is a diagram in which the charging voltage measurement value 80 and the charging voltage drop threshold value 82 set by the charging voltage detection threshold value setting device in the intermittent charging method are plotted with time on the horizontal axis. FIG. 3A shows an example in which a normal corona discharge has occurred up to time T1, but a spark discharge 84 has occurred after T1 and the charging voltage of the dust collector has been cut off. FIG. 3 (B)
The charge voltage drop signal 86 shown in FIG. 3 is a signal generated so that the charge voltage measurement value 80 becomes Hi level only during the charge voltage drop determination area 88 where the charge voltage measured value 80 falls below the charge voltage drop threshold value 82 in FIG. It is. The charge voltage drop signal 86 is generated during a period when no spark discharge is occurring.
2. Output after T3. The power control command 92 shown in FIG. 3 (D) is an AND signal of the charging voltage drop signal 86 of FIG. 3 (B) and the discharge current excess signal 90 of FIG. 3 (C), and is shown in FIG. 3 (C). Discharge current excess signal 90
Is also output by the inrush current flowing to the dust collector, so that even when no spark discharge is occurring, FIG.
Is output between T4 and T5, and a malfunction has occurred.

Power control command 9 output after time T1
2 is a normal detection since it is a signal by the spark discharge 84. The present invention has been made in view of such circumstances, and a spark detection device of an electric precipitator for preventing erroneous detection of spark detection and erroneous tripping of a power supply device due to failure to detect a low-level spark. The purpose is to provide.

[0008]

According to the present invention, in order to achieve the above object, a voltage is continuously or intermittently applied between a dust collecting electrode and a discharge electrode arranged opposite to the dust collecting electrode. And
In a spark detection device of an electric precipitator that collects dust in exhaust gas, a voltage detection unit that detects a charging voltage value applied between the dust collection electrode and a discharge electrode, and a voltage detection unit that detects the voltage. Threshold value setting means for setting a charging voltage lowering threshold value as a criterion for spark generation so as to change in accordance with the charged voltage value, and a charging voltage value detected by the voltage detecting means and set by the threshold value setting means. Determining means for determining the presence / absence of spark by comparing with a charging voltage drop threshold.

According to the present invention, voltage detecting means for detecting a charging voltage value applied between the dust collecting electrode and the discharge electrode, and the voltage detecting means changes in accordance with the charging voltage value detected by the voltage detecting means. Threshold value setting means for setting a charging voltage drop threshold value as a spark generation determination reference, and comparing the charging voltage value detected by the voltage detecting means with the charging voltage drop threshold value set by the threshold setting means. Since the determination means for determining the presence or absence of spark generation is provided, it is possible to reliably detect spark discharge. As a result, it is possible to detect a low-level spark without erroneously determining the same charging voltage drop threshold and discharge current excess threshold in both the continuous charging mode and the intermittent charging mode, which are the two charging modes of the dust collector, thereby suppressing the frequency of spark generation. Further, the non-charging time for preventing the frequent occurrence of sparks can be shortened, and the function of the electric precipitator can be improved.
In addition, the charging voltage that affects the performance of the electric precipitator can be maintained at a high value, and the efficiency can be improved.

According to a second aspect of the present invention, in order to achieve the above object, the threshold setting means includes a voltage dividing resistor for dividing a charged voltage value detected by the voltage detecting means; A delay element for delaying the voltage value or the divided voltage value by a predetermined time. According to the present invention, the threshold setting means includes a voltage dividing resistor for dividing the charged voltage value detected by the voltage detecting means, and a delay for delaying the charged voltage value or the divided voltage value by a predetermined time. Since the elements are provided, it is possible to reliably detect spark discharge with a simple configuration.

According to a third aspect of the present invention, there is provided an electric vehicle comprising: a current detecting means for detecting a discharge current flowing between the dust collecting electrode and the discharge electrode; It is characterized in that it is determined that a spark has occurred when the charging voltage value is equal to or less than the charging voltage drop threshold and the discharge current value detected by the current detecting means is equal to or greater than a predetermined discharge current excess threshold value. I have.

According to the present invention, there is provided current detection means for detecting a discharge current flowing between the dust collection electrode and the discharge electrode, and the judgment means determines that the charging voltage value is equal to or less than the charging voltage drop threshold value. And, when the discharge current value detected by the current detection means is equal to or greater than a predetermined discharge current excess threshold value, it is determined that a spark has occurred. Therefore, it is possible to reliably detect the spark discharge with a simple configuration. Becomes

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an embodiment of a spark detector of an electric dust collector according to the present invention. First, the configuration of the electric precipitator will be described. The electric precipitator 10 includes an AC power supply 14 for operating a precipitator 13 formed by the discharge electrode 11 and the precipitating electrode 12, and a power control element 16 such as a thyristor used for controlling the phase of the AC voltage. ,
A transformer 18 for converting the AC voltage to a voltage usable by the dust collector 13, a rectifier 20 for converting the converted AC voltage to DC, a charged voltage detecting means 30, a charged voltage drop determining means 32, Detection waveform improving circuit 34 according to the present invention
A charging voltage drop detection threshold setting unit 36, a charging voltage drop determination unit 38, a discharge current detection unit 40, a discharge current excess determination unit 42, and a discharge current excess detection threshold setting unit 46;
Discharge current excess determiner 48, phase control device 50, AN
It comprises a D circuit 52 and a phase control circuit 54.

Next, the function and operation of each part of the electric precipitator 10 will be described. The phase of the power obtained from the AC power supply 14 is controlled by the power control element 16 in accordance with a command from the phase control device 50 so as to be power suitable for supplying to the dust collection device 13. Further, after the voltage is increased by the transformer 18, the voltage is converted into direct current by the rectifier 20, and is applied to the discharge electrode 11 of the dust collector 13 to be discharged.
Corona discharge is started between the dust collecting electrode 12 and the dust collecting electrode 12, and the dust collecting operation is performed. At this time, the charging voltage applied between the discharge electrode 11 and the dust collecting electrode 12 is constantly monitored as an output of the charging voltage detecting means 30 using, for example, a voltage dividing resistor.
The discharge current flowing between the discharge electrode 11 and the dust collection electrode 12 is also detected by the discharge current detecting means 4 using a shunt resistor, for example.
It is always monitored as a 0 output.

If a spark discharge occurs between the discharge electrode 11 and the dust collection electrode 12 in the dust collection device 13, the discharge current instantaneously increases and the charging voltage drops. At this time, the charging voltage measurement value 60 and the discharge current measurement value detected by the charging voltage detection means 30 and the discharge current detection means 40 are read by the charging voltage drop determination means 32 and the discharge current excess determination means 42, The power control element 16 is controlled so as to reduce the power consumption. In the discharge current excess determining means 42, the discharge current excess determiner 48 determines whether or not the discharge current measured value is larger than the discharge current threshold value set in advance by the discharge current excess threshold value setter 46. . When the detected discharge current measurement value is larger than the threshold, a signal indicating the discharge current excess is output to the AND circuit 52 of the phase control device 50. Further, in the charging voltage drop determination means 32, the detected charging voltage measurement value 60 is passed through the detection waveform improving circuit 34, and the threshold value of the charging voltage set in advance by the charging voltage drop detection threshold setting unit 36. The charging voltage drop threshold 62, which is a value obtained by adding the above, and the detected charging voltage measurement value 60 are compared and determined by the charging voltage drop determining unit 38. Here, the charged voltage measurement value 6 detected from the charged voltage drop threshold 62
When 0 is lower, a signal indicating a decrease in the charging voltage is output to the AND circuit 52 of the phase controller 50. When the discharge current excess signal 70 and the charging voltage decrease signal 66 obtained in this way are simultaneously input to the AND circuit 52 of the phase control device 50, the AND circuit 52 outputs a power control command to the phase control circuit 54. Then, in response to the power control command, the phase control circuit 54 outputs the power control command to the power control element 16 to control the power applied to the dust collector 13. For example, in order to prevent a continuous discharge at the time of spark generation in the dust collector 13, the gate of the power control element 16 is instantly turned off (charging is stopped), and after a lapse of a predetermined time, gradually returns to the charging voltage at the time of spark generation. A spark-time automatic control circuit is constructed.
This makes it possible to always maintain an appropriate discharge state. Further, in the case where the discharge electrode 11 is disconnected or the foreign matter is mixed, and the discharge electrode 11 and the dust collection electrode 12 are short-circuited, etc., the charging voltage is gradually reduced, and it is determined that the state below the corona start voltage has continued for a certain period of time. The output from the voltage detection means 30 causes the automatic control circuit for spark operation to operate to turn off the gate of the power control element 16 or
A protection circuit (not shown) is configured to cut off the current.

In the above example, the charging voltage drop judging means 32
Also, in the example described above, hardware is used for the discharge current excess determination unit 42 and the phase control device 50. However, it is also possible to read data with an AD converter or the like and perform determination and control processing with software. Good. The spark detection device of the electrostatic precipitator according to the present invention improves the spark detection accuracy by adding a detection waveform improving circuit 34 in the charging voltage drop determination means 32.

FIGS. 2A, 2B, 2C and 2D show the signal processing function of the detected waveform improving circuit 34. FIG. FIG.
(A) is a charging voltage detecting means 30 in the intermittent charging method.
The charging voltage measurement value 60 detected by the above and the charging voltage reduction threshold 62 set by the charging voltage reduction detection threshold setting unit 36 after passing the charging voltage measurement value 60 through the detection waveform improving circuit 34 are compared with time. It is the figure shown on the horizontal axis. FIG. 2 (A)
The normal corona discharge occurred until time T1,
An example is shown in which a spark discharge 64 occurs after T1 and the charging voltage of the dust collecting device 13 is output to the power control element 16 and cut off. According to the present invention, the charging voltage drop threshold 62 changes in accordance with the charging voltage measurement value 60, so that FIG.
The charging voltage drop signal 66 output from the charging voltage drop determining unit 38 shown in FIG.
It remains at the o level. Therefore, even if the discharge current excess signal 70 in FIG. 2C is output from the discharge current excess determination unit 48, the power control command 72 shown in FIG. No malfunction occurs.

If a spark discharge 64 occurs at the time T1, the charged voltage measurement value 60 is reduced by the spark discharge 64, but the tracking of the charged voltage drop threshold 62 is delayed by the operation of the detection waveform improving circuit 34. 2 (A), the charged voltage drop signal 66 = charge voltage drop threshold 62-charged voltage measured value 60 takes a positive value. Accordingly, the charging voltage drop signal 66 shown in FIG. 2B is output during the time constant of the detection waveform improving circuit 34 at the same time as the occurrence of the spark discharge 64. The AND circuit 52 performs an AND operation on the charge voltage drop signal 66 and the discharge current excess signal 70 shown in FIG.
The power control command 72 shown in (D) is obtained.

As described above, according to the present invention, the dust collection electrode 12
Since the detection of the spark generated between the discharge electrode 11 and the discharge electrode 11 is ensured, unnecessary tripping of the power supply device due to the inability to detect a low-level spark can be prevented. In the description of FIG. 1, the detection waveform improving circuit 34 is formed by a first-order low-pass filter. However, the present invention is not limited to this, and a multi-order filter may be formed. The purpose is achieved even with a circuit obtained by adding an operation and a constant. Further, the place where the detection waveform improving circuit 34 is provided also depends on the inside of the charging voltage drop determining means 32 and the discharge current excess determining means 4.
The object is achieved by providing at least one of the two. For example, even if a multi-order delay element is provided in the signal path of the charging voltage drop threshold 62, the object of the present invention is achieved.
The object of the present invention can also be achieved by providing a delay circuit or the like inside the phase control device 50.

[0020]

As described above, according to the spark detection device of the electric precipitator according to the present invention, the voltage detecting means for detecting the charging voltage applied between the precipitating electrode and the discharge electrode is provided. ,
Threshold setting means for setting a charging voltage drop threshold serving as a criterion for spark generation so as to change in accordance with the charging voltage value detected by the voltage detecting means, and a charging voltage value detected by the voltage detecting means; Since the determination means is provided for determining the presence or absence of spark by comparing the charge voltage drop threshold value set by the threshold value setting means, it is possible to reliably detect spark discharge. As a result, it is possible to detect a low-level spark without erroneously determining the same charging voltage drop threshold and discharge current excess threshold in both the continuous charging mode and the intermittent charging mode, which are the two charging modes of the dust collector, thereby suppressing the frequency of spark generation. Further, the non-charging time for preventing the frequent occurrence of sparks can be shortened, and the function of the electric precipitator can be improved. In addition, the charging voltage that affects the performance of the electric precipitator can be maintained at a high value, and the efficiency can be improved.

According to still another aspect of the present invention, the threshold value setting means includes a voltage dividing resistor for dividing the charged voltage value detected by the voltage detecting means, and the charging voltage value or the divided voltage value. Is provided with a delay element for delaying the spark discharge for a predetermined time, so that the spark discharge can be reliably detected with a simple configuration. According to still another aspect of the present invention, the device further includes a current detection unit that detects a discharge current flowing between the dust collection electrode and the discharge electrode, wherein the determination unit determines that the charging voltage value is equal to or less than the charging voltage drop threshold. And, since it was determined that a spark has occurred when the discharge current value detected by the current detection means is equal to or greater than a predetermined discharge current excess threshold,
Spark discharge can be reliably detected with a simple configuration.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment of a spark detector of an electric dust collector according to the present invention.

FIG. 2A is a diagram showing signal processing by the electric precipitator according to the present invention; FIG. 2B is a diagram showing an output state of a charging voltage drop signal according to the present invention; FIG. 2C is a discharge current according to the present invention; The figure which shows the output state of the excess signal (D) The figure which shows the output state of the power control command signal which concerns on this invention

3A is a diagram showing signal processing by a conventional electric dust collector, FIG. 3B is a diagram showing an output state of a conventional charging voltage drop signal, and FIG. 3C is a diagram showing an output state of a conventional discharge current excess signal. (D) is a diagram showing an output state of a conventional power control command signal.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Electric dust collecting device 11 ... Discharge electrode 12 ... Dust collecting electrode 13 ... Dust collecting device 30 ... Charge voltage detecting means 32 ... Charge voltage drop judging means 34 ... Detection waveform improvement circuit 38 ... Charge voltage drop judging device 62 ... Charge voltage Lower threshold 64 ... Spark discharge

Claims (3)

[Claims] 1. An electric precipitator which applies a voltage between a dust collecting electrode and a discharge electrode arranged opposite to the dust collecting electrode by a continuous or intermittent charging method to collect dust in exhaust gas. In the spark detection device, voltage detection means for detecting a charging voltage value applied between the dust collection electrode and the discharge electrode; and spark generation so as to change according to the charging voltage value detected by the voltage detection means. Threshold value setting means for setting a charging voltage lowering threshold value to be a criterion for the determination of sparking by comparing the charging voltage value detected by the voltage detecting means with the charging voltage lowering threshold value set by the threshold value setting means. A spark detection device for an electric dust collector, comprising: a determination unit configured to determine presence / absence. 2. The method according to claim 1, wherein the threshold value setting means includes a voltage dividing resistor for dividing the charged voltage value detected by the voltage detecting means, and a delay element for delaying the charged voltage value or the divided voltage value by a predetermined time. The spark detector for an electric precipitator according to claim 1, comprising: 3. A current detecting means for detecting a discharge current flowing between the dust collecting electrode and the discharge electrode, wherein the determining means comprises:
When the charging voltage value is equal to or less than the charging voltage lowering threshold value and the discharge current value detected by the current detecting means is equal to or greater than a predetermined discharging current excess threshold value, it is determined that a spark has occurred. A spark detector for an electric dust collector according to claim 1.