KR20100005242U - Portable Magnetic Inspection Apparatus - Google Patents

Abstract

The present invention improves portability and relates to a portable magnetic inspection device using direct current and alternating current supplied by one power supply unit. The portable magnetic flaw detector according to the present invention includes a magnetic flaw detector for measuring a defect of a test body; A power supply unit capable of repeatedly charging and supplying power therein to supply power to the magnetic flaw detector; An inverter provided at the rear of the power supply unit and converting direct current into alternating current; A switching switch for supplying or blocking the power output from the power supply unit to the magnetic sensing unit and selectively passing the power through the inverter when the power is supplied from the power unit to the magnetic sensing unit; And a protection circuit unit that cuts off power of the power supply unit when an error occurs in a circuit connecting the magnetic sensing unit, the power supply unit, and the inverter. According to the present invention, it is possible to carry a power supply unit necessary for the operation of the magnetic flaw detector, which can conveniently supply power to the magnetic flaw detector, and can supply direct current and alternating current from one power source.

Magnetic Inspector, Inverter, Surge, Switch

Description

Portable Magnetic Inspection Apparatus

The present invention relates to a magnetic flaw detector used for non-destructive testing, and more particularly, to a portable magnetic flaw detector that can improve portability and selectively use direct current and alternating current supplied by one power supply unit.

The methods for evaluating the integrity of test specimens such as materials, structures, and products are largely divided into fracture and non-destructive tests.

Normally, many fracture tests are easy to check the test results, but there are significant disadvantages. Destructive inspection is a method that destroys and inspects the specimen to check the integrity of the specimen. It has a disadvantage that it cannot be reused because it causes deformation or damage to the specimen after inspection. Therefore, the destruction inspection is not a full inspection but a sampling inspection. Is done. In addition, if the specimen is an important part of a specific product or structure, there is no way to verify the integrity of the specimen by the fracture test.

Therefore, the above problem is solved and the non-destructive test is selected as a reusable test method without damaging the test specimen. In general, after machining such as welding, various non-destructive inspections are performed to investigate defects such as cracks in the internal structure of the machining site.

This nondestructive test is the opposite of the failure test. The type and physical properties of the test specimen shall not change when or during the test and shall not affect the use of the product after the test. In addition, the test results shall maintain the credibility of the results according to the fracture test. To this end, various nondestructive tests are conducted. Non-destructive testing methods are roughly divided into many fields such as ultrasound, radiographic, magnetic, eddy current, leak, acoustic emission, holographic, strain gauge, and thermal imaging. In Edo, the types are further divided according to the technique.

The field of magnetic flaw detection belonging to the present invention is one of the methods for detecting unhealthy parts or flaws (hereinafter referred to as 'defects') occurring in test specimens of ferromagnetic materials. It aims to detect. In other words, magnetic flaw detection is a method of detecting a defect in an object made of ferromagnetic material such as a steel material by using a change in magnetic flux. When an object is defective, the magnetic flux flux is dispersed at the defective part and out of the surface of the object. As it leaks, it is possible to diagnose the defect and the size of the inspected object by measuring the distribution of magnetic flux.

These magnetic examinations are classified into various types according to the test method as follows. That is, it is classified into continuous method and residual method according to the application time of magnetic powder, and classified into fluorescent and non-fluorescent powder according to the type of magnetic powder, and classified into dry method and wet method according to the dispersion medium of magnetic powder. They are classified into direct current, pulse current, alternating current, and impact current, and are classified into axial current conduction, right-angle current conduction, fred method, current penetrating method, coil method, interpolar method, and magnetic flux penetrating method.

The present invention aims to solve the difficulties caused when inspecting the specimen by applying the yoke type using direct current and alternating current among these many methods.

The interpolar method uses a magnetic flaw detector 102 to place a “c” (or horseshoe type) electromagnet or permanent magnet on the surface of the test specimen and generates a magnetic field from the surface of the test specimen to the inside, as shown in FIG. This is a technique to find the exact location of defects on the surface and near the surface of the specimen.

If a magnetic field is generated in the magnetic flaw detector 102 or a permanent magnet is brought close to the surface to find a defect generated in the test specimen, the magnetic field penetrates deep inside the test specimen. At this time, if there is a defect in the test object, as shown in FIG. When the magnetic field does not pass through immediately, distortion occurs to return. Because of this, the stimulus is divided into two, so magnetic particles (ferromagnetic powder dyed in black or red, etc.) are concentrated and attracted between the stimulus and the stimulus. This is the same as splitting a bar magnet into two, which becomes two different bar magnets each having an N pole and an S pole. Between magnetic poles and magnetic poles is the same principle that the magnetic force is stronger than any other part of the magnet and the magnetic particles are concentrated. The interstitial method uses this principle to detect defects on or near the surface of the specimen.

The reason why the detection of defects on or near the surface of the test specimen is important is that cracks that have the greatest adverse effect on the specimen or structure are very likely to exist in this region. Therefore, the present invention can be found to have great significance in that it is intended to solve the difficulties of the field that performs the most important part of non-destructive testing.

On the other hand, when looking at the magnetic screening apparatus 100 of the prior art as shown in Figure 1, by connecting to the power supply panel 101 provided in a fixed place, such as a wall, when the magnetic flaw detection unit 102 operates A magnetic field is generated in the unit 102, and the inspection object 3 can be inspected for abnormality of the inspection site 3a. However, the magnetic flaw detector 100 according to the related art can only use AC power provided at a fixed portion as a power source for driving the magnetic flaw detector 102.

Therefore, by using the AC power provided in the fixed portion, such as a wall, the user must connect the power from the power supply panel 101 to the magnetic flaw detection unit 102 every inspection. For example, the magnetic flaw detection unit 102 uses a very long wire as a power line, or is provided with an extension line (not shown) for connecting the power supply panel 101 and the magnetic flaw detection device 100 to each other. After installation, you will have to recover it after use.

In addition, since there are various inconveniences in supplying power to the magnetic flaw detector 100 as described above, a relatively large inspected object (3), for example, a large inspected object such as a ship or a bridge ( In order to find a defect present in 3), there is a problem in that an extension line connecting the power supply panel 101 and the magnetic examination apparatus 100 to reach the entire area of the inspected object 3 exists.

In the conventional magnetic flaw detector 100, only one power source of direct current or alternating current can be used as a power source of the magnetic flaw detector 102. For example, if DC is used as the power source in the interpolar method, the magnetic flux of the magnetic field is constant, so that the surface and the inside flow at the same magnetic flux intensity, so that internal defects of a certain depth can be measured at the surface, but AC is used as the power source. Compared to the use case, the detection ability on the surface is lowered. On the contrary, when AC is used as a power source, the detection capability of the surface is improved, but the measurement ability of internal defects of a certain depth on the surface is reduced. As a result, when inspecting the inspection portion (3a) of the inspected object (3), there is an inconvenience that the DC power supply device and the AC power supply device must be separately provided for the magnetic flaw detector 100 to be inspected.

The present invention is devised to solve the above problems, and an object of the present invention is to provide a portable magnetic flaw detector that can be easily carried by a user and can supply power for operation of the magnetic flaw detector. Another object of the present invention is to provide a portable magnetic flaw detector that can be supplied to the magnetic flaw detection unit by selecting a direct current and alternating current in one power supply. Still another object of the present invention is to provide a portable magnetic flaw detector that can protect each part under abnormal conditions.

Other objects and advantages of the present invention will be described below, which is not limited to the matters disclosed in the claims of the present invention and the disclosures of the embodiments thereof, but also to the broader scope by means and combinations within the range easily contemplated therefrom. Add that it will be included.

In order to achieve the above object, the present invention, a magnetic flaw detection unit for measuring a defect of the test body; A power supply unit capable of repeatedly charging and supplying power therein to supply power to the magnetic flaw detector; An inverter provided at the rear of the power supply unit and converting direct current into alternating current; A switching switch for supplying or blocking the power output from the power supply unit to the magnetic sensing unit and selectively passing the power through the inverter when the power is supplied from the power unit to the magnetic sensing unit; And a protection circuit unit which cuts off power of the power supply unit when an abnormality occurs in a circuit connecting the magnetic detection unit, the power supply unit, and the inverter.

According to the present invention, the operator can not only inspect the defect of the inspected object but also carry it without being influenced by the physical distance between the power source and the inspected object while carrying the magnetic sensing device. Therefore, defects of the inspected object can be conveniently inspected regardless of the structure, size, and shape of the inspected object.

In addition, since both direct current and alternating current can be supplied by one power supply device, the direct current and alternating current can be alternately supplied to the magnetic flaw detector to inspect the inspection site of the inspected object even without a separate power supply device.

In addition, when abnormal conditions such as overcharge, undervoltage, overheating, overload, short circuit, etc. occur, the power supply is automatically shut down to inspect the defect in a stable state and protect the device.

Other effects of the present invention, as well as those described in the embodiments described above and the claims of the present invention, as well as potential effects that can occur within the range that can be easily contemplated therefrom and potential advantages that contribute to industrial development It will be added that it will be covered by a wider scope.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, the following will describe a preferred embodiment of the present invention, but the technical idea of the present invention is not limited thereto, but may be variously modified and implemented by those skilled in the art.

1. Description of the composition of the present invention

2 is a perspective view of a portable magnetic screening apparatus according to an embodiment of the present invention, Figure 3 is a block diagram of a portable magnetic screening apparatus according to an embodiment of the present invention.

The portable magnetic flaw detector 1 according to the present invention comprises a magnetic flaw detector 2 for measuring a defect of a test body and a separate power supply device 4 for supplying power to the magnetic flaw detector 2. In this case, the power supply device includes a power supply unit 10 charged with a current required for the operation of the magnetic detection unit 2, and a switching switch 20 for applying or blocking current from the power supply unit 10 to the magnetic detection unit 2. And an inverter 40 for converting a current of the power supply unit 10 into an alternating current, and the magnetic flaw detector 2 is connected to the inverter 40.

The magnetic flaw detector 2 serves to measure a defect of a test specimen by using a magnetic field, which has been described in detail in the background art, and a detailed description thereof will be omitted.

The power supply unit 10 receives power from an external power source, and is charged with power required for the operation of the magnetic flaw detector 2 to supply power to the magnetic flaw detector 2.

Since the power supply unit 10 is formed of a battery which can be repeatedly charged, a conventional one is used, and thus a description of a specific configuration will be omitted. The power supply unit 10 as described above is electrically connected to the magnetic flaw detector 2 to supply power to the magnetic flaw detector 2 to thereby detect defects such as cracks or the like on the inspection portion 3a of the inspected object 3. You can inspect it.

The changeover switch 20 is connected to the rear of the power supply unit 10 to electrically connect or disconnect the power supply unit 10 and the magnetic flaw detector 2.

In addition, the switching switch 20 not only connects / blocks the power supply unit 10 and the magnetic flaw detection unit 2 as described above, but also directly connects the power supply unit 10 and the magnetic flaw detection unit 2 to the power supply unit 10. Direct current may be supplied to the magnetic sensing unit 2 from the power source unit 10, or connected to the magnetic sensing unit 2 through the inverter 40 described later by the power supply unit 10. To allow the supply of alternating current.

Since the power stored in the power supply unit 10 is charged in the form of direct current, it is used to supply the power to the magnetic flaw detection unit 2 to perform defect inspection on the inspection site 3a of the inspected object 3. can do. However, in the magnetic flaw detector 2, the defect capability of the inspected portion 3a of the inspected object 3 by using alternating current is higher than that of inspecting the inspected portion 3a of the inspected object 3 using direct current. Since it is excellent, the alternating current is preferably supplied to the magnetic flaw detector 2. To this end, the power supply unit 10 and the magnetic flaw detector 2 are provided with an inverter 40 between the switch 20 and the magnetic flaw detector 2 so as to convert a direct current into an alternating current.

Since the inverter 40 uses a conventional inverter 40, a description of the configuration of the inverter 40 will be omitted. In addition, the current output from the inverter 40 is preferably to have a frequency of 50 ~ 60Hz. However, the alternating current output from the inverter 40 is closer to the waveform of the sine wave than the pseudo sine wave. This is because the closer to the sine wave, the better the detection capability of the inspection site 3a.

On the other hand, the reason for converting the current supplied from the power supply unit 10 into an alternating current and supplied to the magnetic flaw detector 2 is to apply the alternating current interpolar method among the magnetic flaw inspection methods to be suitable for defect inspections on the surface and directly below the surface.

In addition, the inverter 40 is provided between the changeover switch 20 and the magnetic flaw detector 2, but the changeover switch 20 may be configured to supply direct current or alternating current to the magnetic flaw detector 2. When the direct current is selected, the selector switch 20 and the magnetic flaw detector 2 are electrically connected directly, and when the alternating current is selected, the magnetic switch flanks the magnetic flaw detector 2 through the inverter 40. The circuit is configured to be electrically connected.

A surge prevention part 41 is provided in front of the magnetic flaw detector 2 to connect the switch 20 or the inverter 40 to the magnetic flaw detector 2. The magnetic flaw detection unit 2 is a coil wound around an iron core made of a silicon steel sheet having a high permeability, such that the power inside the magnetic flaw detection unit 2 is cut off or inside the magnetic flaw detection unit 2. The counter electromotive force may be generated, and may be reversely energized to the inverter 40 and the power supply unit 10. Since the counter electromotive force may damage the inverter 40 and the power supply unit 10, the surge protection unit 41 is preferably provided in the inverter 40 and the magnetic flaw detector 2.

In addition, an earth leakage breaker 42 is provided between the terminal of the portable power supply, that is, the surge protection part 41 and the magnetic flaw detector 2 to prevent the user from being shocked.

Meanwhile, in order to protect the power supply unit 10 and the inverter 40, the protection circuit unit 30 may be further provided. The protection circuit unit 30 includes an overcharge protection unit 31, a low voltage protection unit 32, an overheat protection unit 33, an overload protection unit 34, and a short circuit protection unit 35.

The overcharge preventing unit 31 detects the voltage and current of the power supply unit 10 to prevent the power supply unit 10 from being charged above the set voltage and current values when the power supply unit 10 is charged.

The low voltage protection unit 32 also senses the voltage and current of the power supply unit 10, and when the power is supplied from the power supply unit 10 to the magnetic sensing unit 2 to discharge the power supply unit 10, the set voltage and current The following prevents the supply of power that is not suitable for the operation of the magnetic flaw detector 2. If the power supplied to the magnetic flaw detector 2 is weakened, it affects the detection of a defect in the inspection portion 3a. That is, when the voltage of the power is lowered, the inconvenience that the self-detection unit 2 can perform a normal operation, the so-called lifting power to check separately, and this is ignored, the voltage output from the power supply unit 10 In spite of this low level, if the magnetic flaw detector 2 is operated, the defect cannot be inspected despite the presence of a defect in the inspected object 3. To prevent this, the low voltage prevention unit 32 is provided to compare the output voltage output from the power supply unit 10 with the set voltage at which the magnetic sensing unit 2 can operate normally. ) To turn off the power automatically.

When the overheat protection unit 33 uses the magnetic flaw detector 2 for a long time, the power supply unit 10 and the inverter 40 continuously sense the temperature, and operate only below the set temperature. To this end, the overheat protection unit 33 sets the first set temperature and the second set temperature so that the power supplied from the power supply unit is cut off when the set temperature is higher than the second set temperature. The first set temperature is usually the upper limit of the temperature range in which the portable magnetic flaw detector 1 operates, and the portable magnetic flaw detector 1 operates normally below the first set temperature. The second set temperature is higher than the first set temperature, but cools the power supply unit 10 and the inverter 40 to be the upper limit of the temperature range in which the portable magnetic sensing device 1 can be operated through cooling. Cooling means, for example, a cooling fan or the like is provided, and when the temperature is above the second set temperature, the power supply unit 10 and the inverter 40 are cooled by the cooling means. In addition, when the temperature is equal to or greater than the second set temperature, the power supplied from the power supply unit 10 is forcibly cut off to stop the entire operation of the portable magnetic inspector 1.

The overload protection unit 34 is provided to prevent a large amount of current from being supplied from the power supply unit 10 to the magnetic flaw detector 2 temporarily. The overload protection unit 34 may send a voltage within a proper voltage and current to the magnetic flaw detector 2.

The short circuit protection unit 35 prevents a short circuit of a circuit connecting the power supply unit 10, the inverter 40, and the magnetic flaw detector 2, thereby improving the stability of the portable magnetic flaw detector 1. The power supplied from the power supply unit 10 passes through the self-detection unit 2, but if the circuit connecting the power supply unit 10, the inverter 40, and the magnetic detection unit 2 is short-circuited, the circuit may be damaged. Since the short circuit protection part 35 is provided, the whole power supply part 10, the inverter 40, the magnetic flaw detection part 2, and the circuit connecting them are protected.

2. Description of the operation of the present invention

Referring to the operation of the portable magnetic examination device of the present invention having the configuration as described above are as follows. First, the power supply device 4 according to the present invention is used as received in the case 50 as shown in Figure 2, the magnetic flaw detection unit 2 is connected through the power line 51.

In order to supply power to the magnetic flaw detector 2, the power source 10 is charged. When the charging of the power supply unit 10 is completed, the inside of the power supply unit 10 generates a voltage and a current of a predetermined level or more.

The switching switch 20 is operated to perform defect inspection on the inspection portion 3a of the inspected object 3 by using the magnetic flaw detector 2. The magnetic power detector 10 is electrically connected to the magnetic power detector 10 which is cut off by operating the changeover switch 20 so that power is supplied from the power supply unit 10 to the magnetic probe 2. It works.

Here, the power switch 10 and the magnetic flaw detector 2 are connected to each other using the switch 20, and whether the power supplied to the magnetic flaw detector 2 is a direct current or an alternating current. Also select. If the user selects the direct current to be supplied to the magnetic sensing unit 2 using the switch 20, the DC power supplied from the power supply unit 10 goes to the magnetic sensing unit 2 without passing through the inverter 40. It is supplied to inspect the inspection site of the inspection object (3). When the AC switch is supplied to the magnetic flaw detector 2 by operating the switching switch 20, the DC power supplied from the power source unit 10 is converted to AC while passing through the inverter 40 to detect the magnetic flaw detector 2. It is supplied to) to inspect the inspection site of the inspection object (3).

In the case where direct current is supplied to the magnetic flaw detector 2 by using the changeover switch 20, defect inspection of the portion directly below the surface is mainly performed at the inspection portion 3a of the inspected object 3, In the case where AC is supplied to (2), defect inspection of the surface part is mainly performed at the inspection portion 3a of the inspection object 3. As described above, by supplying alternating current and alternating current to the magnetic flaw detector 2, defect inspection is performed on the surface and directly under the surface by the one magnetic flaw detector 2 for the inspection part 3a of the inspected object 3. can do.

Here, when the power is supplied to the magnetic flaw detector 2 or cut off, the counter electromotive force may be generated from the magnetic flaw detector 2. The magnetic flaw detector 2 has a coil wound in order to generate a magnetic field. When the power is supplied or cut off, back EMF is generated from the magnetic flaw detector 2 so that the inverter 40 or the power source ( 10) may be damaged, and the reverse electromotive force generated from the magnetic flaw detector 2 is transmitted to the power supply unit 10 and the inverter 40 in the surge prevention part 41 provided in front of the magnetic flaw detector 2. Block it.

On the other hand, since the protection circuit unit 30 is provided, if an abnormality occurs in the power supply unit 10, the inverter 40 or the magnetic flaw detection unit 2, it is protected.

The power supply unit 10 can be repeatedly charged, it should be charged before or after use, when the power supply unit 10 is complete charging over a certain voltage, the overcharge prevention unit 31 operates This prevents the power supply unit 10 from being charged anymore.

When the power supply unit 10 continuously supplies power to the magnetic sensing unit 2, the charging rate is lowered, and thus the voltage output from the power supply unit 10 is lowered, and a low voltage is supplied to the magnetic sensing unit 2. In this case, since the inspection portion 3a of the inspected object 3 cannot be smoothly inspected, the low voltage protection part 32 measures the output voltage of the power supply unit 10 so that the power supply unit 10 When the output voltage drops, the power supply unit 10 to block the output of the power.

And, if the operation for a long time, the power supply unit 10, the inverter 40 is heated to increase the temperature, if overheated, the power supply unit 10, the inverter 40 is damaged. Therefore, the overheat protection unit 33 detects the temperature of the power supply unit 10 and the inverter 40 in real time, and prevents overheating by comparing with the set temperature.

That is, the overheat protection unit 33 sets the first set temperature, which is the upper limit of the normal operating temperature, and the second set temperature, which is the upper limit of the temperature that can be operated in a separately cooled state. When the temperature of the power supply unit 10 and the inverter 40 is lower than the first set temperature, the power supply unit 10 and the inverter 40 operate normally. When the temperature of the power supply unit 10 and the inverter 40 is greater than or equal to the first set temperature and less than the second set temperature, the cooling means is operated to operate in a state of cooling the power supply unit 10 and the inverter 40, If the temperature of the power supply unit 10 and the inverter 40 exceeds the second set temperature, the power output from the power supply unit 10 is cut off to prevent the temperature from rising further.

On the other hand, if it is detected that the current is supplied more than necessary in the magnetic detector 2, the overload protection unit 34 to prevent the power supply to the magnetic detector 2 no longer.

In addition, when the circuit is short-circuited due to an abnormality in the circuit from the power supply unit 10 to the magnetic inspection unit 2, the short circuit protection unit 35 detects this and blocks the operation of the power supply unit 10 to detect the portable magnetic inspection device ( To protect 1).

3. Description of technical advantages of the present invention

Electromagnets or permanent magnets using direct current can penetrate deeply under the surface of the specimen due to the nature of the magnetic field to detect defects present therein. . This causes the detection ability of the most important defect to deteriorate. However, the detection of defects occurring directly under the surface and expected to grow toward the surface cannot be ignored.

Normally, magnetic probes using permanent magnets, which do not require power supply, are not used in the type where the polarity of each "c" (horseshoe) magnetic pole does not change. The reason is that the magnetic field is continuously generated at the stimulus, so it is not easy to handle because of the strong adhesion of 18Kg (lifting power) to the specimen during the test.

Therefore, the magnetoresistive device of electromagnet type using direct current electricity is used a lot. However, it is not easy to find a direct current power source in the industrial sites where the most nondestructive testing is performed. Since almost all equipment supplied and used in industrial sites use AC power supplied by KEPCO, electric facilities are mostly facilities that can supply AC. Therefore, to receive DC power, you must carry a battery that can supply DC power separately. If the battery is supplied with power only, it can be very useful for the inspection where there is no power supply. However, most of the inspection quantity is large, so the battery capacity must be increased to prolong the use time. This will also increase the weight of the battery. And the problem that the defect detection capability of the most important test object will fall will arise.

For this reason, an AC type magnetic flaw detector made of an electromagnet using AC electricity is used in parallel. The electromagnet using alternating current electricity has the polarity of the "c" (horseshoe-shaped) magnetic pole continuously changing to the north pole and the south pole, which causes the epidermal effect in which the electromagnetic field applied to the test object concentrates close to the surface of the test object. do. Due to this skin effect, the detection sensitivity of defects occurring on the surface of the test specimen is very excellent, and the detection sensitivity of the most important defect is also increased. It can be directly supplied with power in the field equipment, and is also used because it has excellent detection sensitivity of defects occurring on the surface of the specimen.

However, despite these advantages, there are disadvantages. It is a fact that it is very difficult to supply AC power when inspecting in complex places or in high places, in places where there are no power facilities or in remote areas. If the test specimen is far from the power source, the power line should be laid several hundred meters or more and the generator should be mobilized. In particular, it is very difficult to inspect the construction site of bridge construction site, upper part of building, large ship, and offshore structure. As a result, both an electromagnet using a direct current having good portability of the equipment and an electromagnet type magnetic inspection device using an alternating current having good detection sensitivity of defects are required. There is a tremendous inconvenience that must be done.

At this time, it is the present invention that utilizes the advantages of these two types of magnetic flaw detectors and solves the disadvantages. That is, when using the switch 20 to selectively pass through the inverter 40 when supplying power from the power supply unit 10 to the magnetic flaw detection unit 2 to use the existing DC, AC equipment as one power supply device If the electromagnet also uses AC type electromagnet, there is no need to carry the electromagnet type equipment using the direct current. In this case, the ability to detect defects in the specimen and the reliability of the inspection are very good, and the time required for inspection and the maintenance cost of equipment are also very good.

In addition, if the main power is cut off during the inspection, or if the wire is disconnected due to the sharp structure of the site, or the wire is squeezed by other objects, the test object will be delayed due to the interruption of the power supply. B. There is a danger of causing electric short-circuit (short-circuit), fire, or electric shock to other facilities, equipment, and products. And when leakage current, surge voltage, etc. occurs in the welding machine or other equipment used at the inspection site, current flows through the earth wire of the test equipment's power line, which cuts off the power system and damages other connected equipment. May cause.

In other words, in the field in which the present invention is used, there is a special situation in which a defect of the magnetic sensing device causes a problem in the power supply system of the site, causing a serious problem that paralyzes the peripheral work. In addition, there is also a risk of electric shock when a problem occurs because the magnetic sensing device is always carried by the hand. In order to closely respond to this problem, the protection circuit unit 30 according to the present invention includes an overload protection unit 34 to cut off power from the power supply unit 10 when the power supply unit 10 or the inverter 40 is overloaded. When the short circuit occurs in the circuit connecting the power supply unit 10, the inverter 40, and the magnetic flaw detection unit 2 with the short circuit protection unit 35, the power supply of the power supply unit 10 is cut off.

In addition, in the field of the present invention, the magnetic flaw detection device of the interstitial method has an electromagnet inside. Regardless of direct current or alternating current, when the electromagnet supplies power and turns it off, a surge occurs. It is from 10V to 100V at the moment. Electromagnet coil of the magnetic flaw detector of the interpolar method serves as the primary coil. The frequency of back EMF generated when this is off is equal to the number of times of switching on and off the magnetic flaw detector.

During magnetic inspection, turn on the power and supply the DC and AC power to the electromagnet to magnetize the magnet and generate the magnetic field inside the test body for 3 seconds or more. Determine the shape of the magnetic particles and check for the presence of defects. The power is turned off to move the magnetic probe to the next inspection range. If the magnetic field is generated by continuously turning on the power without turning the power off, the magnetic flaw detector will stick strongly to the surface of the specimen (DC: 4.5Kg, AC: 18Kg lifting power), making the equipment difficult to move.

In general, since the test is performed by overlapping 10% or more of the interval between magnetic poles and magnetic poles of the magnetic probe, a large number of movements occur when the test range is long or wide. At this time, since the power of the equipment must be turned off, the number of occurrences of the counter electromotive force increases. Literally repeating the on and off of the magnetic probe during the test. The counter electromotive force generated in this way flows through the power line of the magnetic flaw detector and flows into the power supply device 4, that is, the inverter 40 used in the present invention, which causes continuous load or damage to the circuit.

Although there is usually a function to prevent a slight surge at the output of the inverter, this function is typically used to protect the equipment from lightning, etc., and the surge recognition voltage reaches a range of tens of thousands of volts (V). It is done. Therefore, the surge voltage of 10V to 100V generated by the magnetic flaw detector of the present invention cannot be detected and flows into the circuit as it is. In addition, the surge protection electronic components, baristas, also have a lifespan and are damaged if the surge voltage continues to exceed the limit. In the case of an inverter with a built-in surge protection circuit, the circuit breaker of the inverter is activated due to a surge, which stops the overall operation of the equipment. Because of this, conventional equipment cannot add the long continuous inspection ability to achieve in the present invention.

Therefore, in order to protect the circuit of the present invention, a surge protection circuit that detects and removes a surge voltage in a low voltage range of several 10V to several 100V generated every moment in a magnetic sensing device should be configured. To this end, the surge recognition voltage of a surge protection electronic component, such as a barista, should be configured separately so that the range of the surge voltage generated by the magnetic inspection apparatus is set. The range should be a surge interruption voltage range of several 10V to several 100V as a result of the measurement. This is the reason why the surge protection part 41 is separately configured in the present invention.

In the magnetic examination, there is a very important thing to verify the performance of the magnetic examination apparatus used for the test of the test specimen. It is a procedure to check and verify whether the magnetic force sufficient to detect the defect of the specimen can be held and applied. This is called the lifting power of the magnetic flaw detector.

In the case of the electromagnet type, the magnetic flaw detector can be supplied with power and adhered to a rectangular ferromagnetic specimen (Steel material) of a certain weight. It is tested and verified. This verification method is very important in the interstitial method to which the present invention belongs during the magnetic examination. Equipment that does not pass this test cannot be used for inspection, and if it fails to be verified again during or after the test, the test specimen shall be totally retested with other equipment verified by lifting power.

Due to the characteristics of the portable magnetic sensing device according to the present invention, when the voltage of the battery is lowered, the output voltage is also lowered. Of course, it will maintain the normal output voltage to a certain range, but the output voltage may be lowered depending on the gradually decreasing battery voltage. When the output voltage is lowered as described above, the magnetic force of the magnetic inspection device using the electromagnet method is also lowered. When the magnetic force is lowered, the lifting power is lowered, and when it is lower than the standard for the performance verification of the equipment, it also adversely affects the reliability of the test. The reason is that when the magnetic force applied to the test specimen is lowered, the magnetic force generated by the defect is also weakened, and the magnetic powder of the ferromagnetic material is not coagulated properly, so that the defect cannot be detected by the naked eye of the inspector.

Therefore, as in the present invention, when conducting a magnetic examination using a portable magnetic examination apparatus, checking the lifting power at any time is the only way to maintain the reliability of the examination results. However, the weight of the lifting power check specimen is too heavy to carry on site.

For this reason, the present invention intends to increase the reliability of the test result by separately providing the low voltage preventing unit 32. The present invention is provided with a low voltage prevention part 32 in the portable magnetic flaw detector of the present invention to eliminate the inconvenience of frequently checking the lifting power during the test object and the waste of re-inspecting the test piece. When the voltage supplied (output) to the magnetic flaw detector 2 is lower than the specified direct current or current voltage by defining a pre-validated voltage that can pass through the circuit, the circuit is cut off by the protection circuit of the portable magnetic flaw detector of the present invention. The power supply to the magnetic probe is interrupted and no longer available. That is, the protection circuit unit 30 according to the present invention has a low voltage protection unit 32 to cut off the power output from the power supply unit 10 when the voltage output from the power supply unit 10 becomes less than or equal to the set voltage. This is to effectively verify the performance of the portable magnetic flaw detector according to the present invention. This enables the portable magnetic flaw detector of the present invention to eliminate the risk factors that need to be retested without knowing that the lifting power verification performance is less than the specified lifting power verification performance. It has the effect of letting the inspector know about it so that it can stop the test and take the necessary action.

On the other hand, the protection circuit unit 30 has an overheat protection unit 33 to operate the cooling means when the power supply unit 10 or the inverter 40 is above the first set temperature, the second set higher than the first set temperature When the temperature is reached, the power supply of the power supply unit 10 is cut off. The cooling function of the protection circuit unit 30 is not a function of simply cooling to increase the charging efficiency of the battery.

The portable magnetic screening device of the present invention is used in a very unfavorable industrial site. The ambient air temperature is also very high depending on the surrounding equipment or environment, and after the equipment is operated due to continuous heat generation. After a certain time, the temperature rises rapidly. Then, the temperature rises rapidly to prevent damage to the components constituting the circuit of the inverter temperature rise protection circuit of the inverter is activated and the power supply of the inverter is cut off. This affects stable long-term inspection in the field, which is the purpose of the present invention, so the present invention defines the first set temperature and the second set temperature to operate the cooling means when the respective ranges are exceeded or the power supply unit 10 ) Is to achieve the purpose of the present invention by cutting off the power supply. This is different from the battery overheating prevention device which is conventionally configured, and aims to protect the circuit constituting the inverter 40 and to enable continuous long time use of the inverter 40.

If the cooling device is operated by measuring the temperature inside the case 50 of the power supply device 4, the cooling effect is not exerted in the same device configuration as the present invention. You will not be able to stop. The reason is that as the load on the inverter 40 continues, some parts of the inverter 40 will continue to generate heat, at which time the actual heat generated by the parts will continue to accumulate and rise quickly, whereas in the case of the device Since the internal temperature will rise more slowly than this, there is a problem that the operation of the cooling means is delayed to sense the temperature inside the case and to cool the device, so that some parts of the inverter 40 before the cooling means can perform its intended function. This will cause damage to the circuit already beyond the limit temperature. As a result, there is a problem that the continuous inspection cannot proceed.

Accordingly, the present invention attaches a temperature sensor directly to a component (transformer, resistor, power transistor, etc.) that is expected to generate heat among components constituting the circuit of the inverter 40, thereby increasing the continuous temperature rise according to the load on the inverter 40. When the sensor senses it immediately and reaches the first set temperature, the cooling means is immediately activated to immediately cool the rising temperature of the circuit. When the temperature continues to rise to reach the second set temperature, the power supply of the power supply unit 10 is cut off to protect the circuit of the inverter 40.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention belongs may make various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention, but are intended to be described, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas falling within the scope of the present invention should be interpreted as being included in the scope of the present invention.

1 is a perspective view of a magnetic flaw detector according to the prior art.

2 is a perspective view of a portable magnetic examination device according to an embodiment of the present invention.

3 is a block diagram of a portable magnetic examination device according to an embodiment of the present invention.

4 is a principle diagram for inspecting a test object by applying a yoke type.

<Description of Major Symbols in Drawing>

1: portable magnetic flaw detector 2: magnetic flaw detector

3: test object 3a: inspection site

10: power supply unit 20: switching switch

30: protection circuit part 31: overcharge protection part

32: low voltage protection unit 33: overheat protection unit

34: overload protection part 35: short circuit protection part

40: inverter 41: surge protection part

42: leakage circuit breaker 50: case

51: power line 101: power supply panel

102: magnetic detector 103: power line

4: power supply

Claims (7)

Magnetic flaw detection unit for measuring a defect of the test body; A power supply unit capable of repeatedly charging and supplying power therein to supply power to the magnetic flaw detector; An inverter provided at the rear of the power supply unit and converting direct current into alternating current; A switching switch for supplying or blocking the power output from the power supply unit to the magnetic sensing unit and selectively passing the power through the inverter when the power is supplied from the power unit to the magnetic sensing unit; And And a protection circuit unit which cuts off power of the power supply unit when an error occurs in a circuit connecting the magnetic detection unit, the power supply unit, and the inverter. The method of claim 1, The protection circuit unit, Portable magnetic sensing device, characterized in that it includes an overcharge preventing unit for preventing the power supply unit from being charged above the set voltage. The method of claim 1, The protection circuit unit, And a low voltage prevention unit for cutting off the power output from the power supply unit when the voltage output from the power supply unit is less than or equal to the set voltage. The method of claim 1, The protection circuit unit, Cooling means is activated when the power supply unit or the inverter is higher than the first set temperature, and the overheat prevention unit for shutting off the power supply of the power supply unit when the second set temperature is set higher than the first set temperature is included. Portable magnetic flaw detector. The method of claim 1, The protection circuit unit, And an overload prevention unit which cuts off power from the power unit when the power unit or the inverter is overloaded. The method of claim 1, The protection circuit unit, And a short circuit protection unit which cuts off the power supply of the power supply unit when a short circuit occurs in a circuit connecting the power supply unit, the inverter, and the magnetic inspection unit. The method of claim 1, Portable magnetic flaw detection device further comprises a surge protection unit in front of the magnetic flaw detection unit to block the transfer of back EMF generated when the power is supplied to or cut off the magnetic flaw detection unit.

Images