JPH0332019B2 - - Google Patents

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a device for detecting minute defects such as pinholes existing on the glass lining surface of glass lining equipment, etc. The present invention relates to a type of detector that detects defects by applying a DC voltage of about 20,000 V to the metal base material of lining equipment and detecting defects by spark discharge generated through pinholes.

(Prior Art) This type of detector requires a DC high voltage of about 20,000 V as a spark starting voltage to cause spark discharge due to dielectric breakdown at the pinhole portion. As a means to generate such a high DC voltage,
Conventionally, two methods have been known: (1) a method in which high-frequency voltage is boosted using a flyback transformer and rectified into a high DC voltage; and (2) a method in which the commercial frequency power supply voltage is boosted and rectified using a power transformer and then converted into a high DC voltage. ing. However, as a DC high voltage power supply for a pinhole detector, high voltage can be obtained with a small number of windings (1), but the power is insufficient, so the insulation resistance between the glass lining surface and the ground must be 50MΩ or less. A significant voltage drop is observed, which poses a problem in terms of practical functionality. (2) has a large transformer and many windings per volt due to its low frequency, and the entire device is large and heavy at about 170 kg, making it difficult to handle and transport. Measurement accuracy is low due to lack of stability and uneven breaking current.

In the conventional pinhole detectors of any of the above methods, spark discharge is a transient phenomenon, and from the viewpoint of control, it is difficult to continuously generate spark discharge in a stable state, which is unique to glass-lined equipment. This prevents tests from being carried out on areas with unusual shapes.

(Problems to be Solved by the Invention) The present invention has been made in order to provide a solution to the above-mentioned problems of conventional pinhole detectors.
In other words, it has good transportability, improves the stability and safety of discharge tests using high DC voltage by improving the power supply characteristics, and also prevents short circuits between the high DC voltage of the probe's detection electrode and the ground part of the metal base material. It is an object of the present invention to enable continuous testing even in the peripheral area of the glass lining where similar conditions occur.

(Means for Solving the Problems, Effects, and Embodiments) In order to solve the problems of the prior art described above, the present invention provides a step-up transformer driving amplifier that supplies current from a variable DC voltage power source to the primary side of a step-up transformer. A method is adopted in which the pulse voltage generated on the secondary side is rectified by switching control using a transistor to generate DC high voltage.This makes the DC high voltage output generator smaller and lighter, and also increases the DC high voltage output In order to perform stable spark discharge tests, we installed a voltage stabilization circuit that controls the voltage in a variable DC voltage power supply, and a DC high voltage overcurrent cutoff circuit that cuts off overcurrent during discharge loads on the primary side of the step-up transformer. Furthermore, by switching between the two circuits mentioned above, an auto-balance circuit is installed to maintain a constant voltage at no load and a set constant current at discharge load, making it possible to continuously test specially shaped parts of the glass lining surface. This is what I did.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be specifically explained in detail with reference to the accompanying drawings, which are block diagrams showing circuits of one embodiment.

() DC high voltage generation circuit The DC voltage variable power supply 1 includes, for example, a 12V DC power supply 2 obtained by rectifying the secondary side 14V of an AC 100V power transformer with a bridge diode (not shown) and a DC voltage variable power supply connected to it. Consists of IC3. The capacity of the power supply is approximately 20V and 3A.
DC voltage variable IC3 is for DC voltage variable as described below.
0 to 0 under the control of IC operating transistor 4
DC output with variable voltage in the 16V range. (below,
A transistor is sometimes abbreviated as TR, its base as B, its collector as C, and its emitter as E.

This output is the a contact (contact that closes when the relay operates) 6 of the high voltage output cutoff relay 5, which will be described later.
is connected to one end of the primary side of the step-up transformer 7, and the other end is connected to the negative side 9 of the circuit via C-E of the step-up transformer drive amplifier 8, which is a TR. The step-up transformer drive amplifier 8 is connected to the 2V, 100/120Hz power supply which is full-wave rectified from the secondary side of the 50/60Hz power transformer and is controlled by switching, so its C-E
The current flowing through the primary side of the step-up transformer 7 is
This becomes an intermittent current of 100/120 Hz, and a pulse-like high voltage is generated on the secondary side of the step-up transformer 7.

The generated high voltage is passed through the high voltage rectifier diode 10.
A rectified DC high voltage of about 20,000 V can be obtained from the high voltage output terminal 11 connected to the anode side of the high voltage output terminal 11 and the cathode side of the high voltage output terminal 11. High voltage output 1
1 is connected to a pinhole detection electrode of a probe 12. A smoothing capacitor 14 for ripple removal is connected between the high voltage output terminal 11 side and the ground terminal 13. The glass-lined device A to be tested is shown by a base material A' and a glass lining surface A', and the base material A' is connected to the terminal 13 and grounded. In this way, a spark discharge S is generated between the DC high voltage detection electrode of about 20,000 V of the probe 12 and the base material A' at the defective part d, which is generally called a holiday such as a pinhole on the glass lining surface A'.

() DC high voltage output voltage stabilizing circuit In order to stabilize the DC voltage generated at the high voltage output terminal 11, the set control voltage _v1 is applied from the DC high voltage output voltage regulator 15 to the voltage differential amplifier 16.
Enter. On the other hand, the voltage v ₂ is sent to the amplifier 1 from the DC high voltage (voltage) detection point 19 between the output voltage stabilizing resistor 17 and the voltage voltmeter 18 connected between the high voltage output terminal 11 side and the minus side 9.
6 and operates the amplifier 16 by comparing it with the control voltage _v1 input.

The output side of the voltage differential amplifier 16 passes through the reverse voltage blocking diode 20 to provide the variable DC voltage.
Connected to B of drive transistor 4 of IC3. The voltage adjustment terminal of the DC voltage variable IC 3 is connected to the negative side 9 of the drive transistor 4 via C-E, and when a positive voltage is applied to B, conduction occurs between C and E, allowing the DC voltage to be varied. The DC output voltage of IC3 is now reduced.

Detection point 1 input to voltage differential amplifier 16
9 is higher than _the control voltage v ₁ , its output becomes positive, and the drive transistor 4 lowers the DC output voltage of the DC voltage variable IC 3, and as a result, the DC high voltage at the high voltage output terminal 11 decreases. Output voltage decreases. In this way, when the DC voltage output voltage decreases and the voltage v ₂ at the voltage detection point 19 also decreases and becomes lower than the control voltage v ₁ , the output of the voltage differential amplifier 16 becomes negative and the drive transistor 4 is turned off. When the drive transistor 4 is turned off, the DC voltage variable IC 3 increases its DC output voltage again. By this switching, the DC high voltage at the high voltage output terminal 11 is maintained at a constant voltage according to the setting of the regulator 15.

() DC high voltage overcurrent break circuit To activate the DC high voltage generation circuit 1, open the a contact 6 of the high voltage output cutoff relay 5 mentioned above.
is held closed. Therefore, the high voltage output cutoff relay 5 connects the +12V power supply 21 obtained by rectification from the secondary side of the power transformer to the C-E of the relay control transistor 22 via the relay 5.
This TR2 is connected to 9 on the negative side through
A manual relay control switch 23 from a +12V power supply 21 is connected to No. 2B via a resistor 24. Therefore, by first closing the relay control switch 23, a positive voltage is applied to B of TR 22, which causes C- of TR 22 to be applied.
E becomes conductive, the relay 5 becomes operational, and the a contact 6 is maintained in the closed state.

During the test of the glass lining surface A″ of equipment A in the operating state of DC high voltage generation circuit 1,
Spark discharge S from the probe 12 to the pinhole part d
In order to prevent damage to equipment due to large current and ensure the safety of operators, when overcurrent occurs and current flows and the load state occurs, the overcurrent is set to cut off the high voltage output so that the current value is below the set value of 1.7 mA. It is cut off by opening the a contact 6 of the relay 5.

In order to interrupt the overcurrent, a control voltage v ₃ corresponding to the interrupting current value is input from the interrupting current regulator 25 to the current differential amplifier 26 . On the other hand, a voltage v ₄ corresponding to the load current value is inputted to the amplifier 26 from the DC high voltage (current) detection point 28 between the ground 13 side and the high voltage ammeter 27 connected to the negative side 9, and the control voltage v ₃ is input to the amplifier 26. The amplifier 26 is activated by comparison with the input. The output side of the current differential amplifier 26 is a reverse voltage blocking diode 29.
It is connected to B of the current interrupting auxiliary transistor 32 through the current interrupting contact 31 of the auto balance changeover switch 30, its E is connected to the negative side 9, and its C is connected to B of the relay control transistor 22. .

If the voltage v ₄ of the DC high voltage (current) detection point 28 input to the current differential amplifier 26 is higher than the 1.7 mA cutoff current value control voltage v ₃ , its output becomes positive, and the C- of the auxiliary transistor 32 E is electrically connected, and BE of the relay control transistor 22 is short-circuited. Thereby, the relay control transistor 25 is turned off, the a contact 6 of the high voltage output cutoff relay 5 is turned off, the DC high voltage generation circuit 1 is opened, and the overcurrent is cut off.

Detection point 2 input to current differential amplifier 26
If the voltage v ₄ of 8 is lower than the control voltage v ₃ of the breaking current value of 1.7 mA, the auxiliary transistor 32 is turned off and the relay control transistor 22 is kept on.

After the DC high voltage generating circuit 1 is opened to cut off the overcurrent, the circuit 1 is turned on by the relay control switch 23 in order to cause the pinhole detector to generate a DC high output voltage again. To stop the generation of DC high voltage output voltage as desired, use relay control switch 2.
3 turns off the DC high voltage generation circuit 1.

() Ord balance circuit When the tip of the probe 12 approaches the glass lining surface A'' to within 20 mm while detecting a pinhole on the glass lining surface A'' of the glass lining device A, a charge current to the deposits is generated. Continuous discharge is likely to occur due to corona discharge, near the boundary between the glass lining surface of the nozzle part of the device and the outside surface of the device where the base material A′ is exposed.
Alternatively, when performing a pinhole inspection on a specially shaped part such as a partially glass-lined part, a discharge occurs directly to the base material A' without passing through the glass-lined surface A''.This discharge is close to a continuous discharge. When this discharge current exceeds a set cutoff current value of, for example, 1.7 mA, the DC high voltage overcurrent cutoff circuit 11 is activated to perform cutoff and the high voltage output becomes no voltage.
Therefore, to continue the test, each time a cutoff operation is performed,
At the same time, the DC high voltage generating circuit 1 must be turned on by operating the relay control switch 23, which has been turned off. This is extremely complicated and greatly reduces testing efficiency.

In order to solve this problem, in the present invention, the above-mentioned autobalance changeover switch 30
is switched from the overcurrent cutoff side contact 31 to the autobalance contact 33, and the autobalance contact 33 is connected to B of the drive transistor 4 of the DC voltage variable IC device 3. The output side of the voltage differential amplifier 20 is also connected here as described above.

According to this autobalance circuit, when the DC high-voltage output voltage is set to a desired voltage and pinhole detection is being performed, a current exceeding the set current value of, for example, 1.7 mA flows through the high-voltage ammeter 27 due to the above-mentioned direct discharge. When that voltage is generated at the DC voltage (current) detection point 28, the output of the current differential amplifier 26 becomes positive, and the reverse current blocking diode 2
9. Through the auto balance changeover switch 30,
This time, we will introduce B of the drive transistor 4 of the DC voltage variable IC 3 from the autobalance contact 33.
As a result, this transistor 4 conducts and the output voltage of the DC voltage variable IC device 3 decreases, resulting in a decrease in the high voltage discharge current and a voltage of 1.7 m.
A, and the voltage at the DC high voltage (current) detection point 28 also decreases.

In this way, when the high voltage discharge current becomes less than the set value of 1.7 mA, the output side of the current operating amplifier 26 becomes negative. At this time, if the DC high voltage output voltage is lower than the set value, the DC high voltage (voltage)
The input voltage from the detection point 19 is also applied to the voltage differential amplifier 1.
6, the positive voltage is not applied to the drive transistor B from the output side. In the end, since no positive voltage is applied to the drive transistor 4 from any path, it is turned off, and the output voltage of the DC voltage variable IC 3 rises again.

In this way, when there is no load on the high voltage output side, the voltage set by the high voltage output voltage regulator 15 is maintained, while when load current flows due to discharge etc., the current is maintained at the set current value of 1.7 mA. Continuous discharge becomes possible and continuous testing becomes possible.

Auto balance circuit () changeover switch 3
0 is provided near the detection electrode of the probe 12 so that it can be switched to the autobalance contact 33 only while the operator presses the push button, making continuous testing of specially shaped parts and parts of the above-mentioned glass lining equipment easy. Now you can do
Operator safety is also ensured.

(Effects of the Invention) According to the present invention, it is possible to use a small, lightweight and portable device that weighs about 10 kg as a pinhole detector on a glass lining surface, making it easy to handle and improving work efficiency. Functionally, it is possible to stably obtain high DC voltage for spark discharge, which enables reliable defect detection, cuts off overcurrent during discharge loads, ensures the safety of workers and equipment, and furthermore, By realizing automatic coexistence of constant voltage and constant current during discharge load, effects such as continuous testing of specially shaped parts of glass-lined equipment without the need to reset each time the circuit is interrupted can be achieved.

[Brief explanation of the drawing]

The attached figure shows a circuit diagram of one embodiment of the glass lined surface pinhole detector of the present invention. 1...DC voltage variable power supply, 2...DC power supply, 3
...IC for variable DC voltage, 4...For variable DC voltage
IC operating transistor, 5... Relay for high voltage output cutoff, 6... A contact, 7... Step-up transformer, 8
...Step-up transformer driving amplifier, 9...Minus side, 10...High voltage rectifier diode, 11...High voltage output terminal, 12...Probe, 13...Earth side terminal, 14...Smoothing capacitor, 15... ...DC voltage output voltage regulator, 16...Voltage differential amplifier, 17...Output voltage stabilizing resistor, 18...High voltage voltmeter, 19...DC high voltage (voltage) detection point, 2
0, 29... Reverse voltage blocking diode, 21...
Relay drive power supply, 22... Relay control transistor, 23... Relay control switch, 24... Resistor, 25... Breaking current regulator, 2
6... Differential amplifier for current, 27... High voltage ammeter,
28...DC voltage (current) detection point, 30...Auto balance changeover switch, 31...Overcurrent cutoff side contact, 32...Auxiliary transistor for overcurrent cutoff,
33...Auto balance side contact,...DC high voltage generation circuit,...DC high voltage output voltage stabilization circuit,
...DC high voltage overcurrent cutoff circuit, ...Auto balance circuit, A...Glass lining equipment,
A′...Base material, A″...Glass lining surface, v ₁ ...
...Control voltage, v ₂ ...Voltage detection point voltage, v ₃
...Breaking current control voltage, v ₄ ...Load current value voltage.

Claims (1)

[Claims] 1. A DC high voltage obtained by connecting a variable DC voltage power source to the primary side of a step-up transformer, intermittent energization by a step-up transformer driving amplifier, and rectifying the pulse voltage generated on the secondary side of the step-up transformer. A glass lining characterized in that a DC high-voltage output voltage stabilizing circuit and a DC high-voltage overcurrent protection circuit and disconnection circuit are provided for a device in which a spark is discharged into a pinhole on a glass lining surface by guiding the spark to a probe part. Surface pinhole detector. 2 Configure an autobalance circuit by providing an autobalance changeover switch that switches from the middle of the DC high voltage overcurrent or disconnection circuit to the DC high voltage output voltage stabilizing circuit, which maintains constant voltage during no load and maintains constant voltage during discharge load. A pinhole detector on a glass lining surface according to claim 1, which is automatically controlled while maintaining a constant current. 3. A pinhole detector on a glass lining surface according to claim 2, wherein an autobalance changeover switch is attached to the probe section.