Industry news-Henan LongJian Electric Power Equipment Co., Ltd.

Analysis of Common Faults in Mining Transformers

2021-04-29

During the use of transformers, there are various types of faults that occur due to differences in the duration of use, the degree of damage caused by overvoltage and overcurrent, and the different situations of use and maintenance. Therefore, in order to detect faults in a timely manner, analyze and eliminate them, and improve the ability and accuracy of fault detection and diagnosis, it is necessary to fully utilize various diagnostic techniques and integrate various historical data of equipment operation. Here are some opinions on the common fault diagnosis of transformers.1、 Inspection of Transformer Faults1. Look. Carefully inspect every part of the transformer from the outside to the inside by detecting any abnormal phenomena such as color when a fault occurs Leakage of oil. During the operation of transformers, oil leakage is a common phenomenon that can be easily identified by humans on the outer body of the equipment. Small transformers are installed in some shells, and attention should be paid to the bottom plate on or below the shell during inspection. Oil leakage varies greatly, mainly due to poor sealing between the oil tank and components, defects in welding or casting parts, equipment overload, or impact vibration. In addition, internal faults in transformers during use can also cause an increase in transformer oil temperature, volume expansion, and oil leakage Due to temperature, humidity, ultraviolet radiation, or the presence of acids, salts, etc. in the surrounding air, the surface paint film of the box may crack, bubble, or peel off. Overvoltage can cause surface cracks and discharge marks on porcelain parts, porcelain sleeves, and porcelain bottles. Loose screws in the fastening part of the porcelain bottle terminal wiring can cause surface contact surface peroxidation and discoloration.The discoloration of the moisture absorbent inside the dehumidifier is caused by excessive moisture absorption, damaged gaskets, and excessive water volume in the turbid room. Typically, the material of the moisture absorbent is alumina, silicone, etc., and it appears blue. If it turns pink, it needs to be regenerated.2. Listen. During normal operation, the transformer emits a uniform buzzing sound. If uneven or other noises are produced, it is considered an abnormal phenomenon.① The sound is louder and sharper than usual, partly due to overvoltage in the power grid, and partly due to transformer overload.② If a "chirping" sound is made and the high-voltage fuse is blown, it is because the tap changer is not closed properly. If a slight "squeaking" sound is produced, it is a discharge sound and a poor contact of the tap changer.③ If the transformer emits a "whooshing" sound and a "creaking" sound, and the sound is loud and chaotic, it may be a problem with the transformer's iron core.④ There is a hissing sound of discharge in the sound, and corona or blue sparks can be seen at night, which may be due to partial discharge of the transformer's wiring porcelain bottle.⑤ If you hear a "crackling" sound while standing in front of the transformer, it may indicate poor grounding or static discharge from ungrounded metal parts. At this time, the operation of the transformer should be stopped for maintenance.⑥ During operation, there is a loud and uneven cracking sound, which may be due to insulation breakdown of the transformer. If the dull "crackling" sound is the discharge of the conductor through the transformer oil to the shell.⑦ When there is a "gurgling" sound of water boiling in the transformer, it may be due to interlayer or turn to turn short circuit in the winding of the transformer. At this time, the operation of the transformer must be stopped for maintenance.3. Testing. The diagnosis of transformer faults based on sound, color, and other phenomena can only be used as a preliminary analysis and judgment on site, because the condition of any equipment cannot be directly reflected by a single aspect. There are many factors that can sometimes create false impressions. Therefore, it is necessary to measure and conduct comprehensive analysis in order to accurately identify the cause of the fault and the nature of the accident, and propose a more complete and economically reasonable solution.① Measurement of insulation. Mainly used to determine the insulation condition of windings, this is a relatively simple and effective method. Insulation resistance measurement usually uses an insulation resistance meter, and high-voltage transformers above 3KV generally use a 2500V insulation resistance meter. Measurement item: Measure the insulation resistance of the winding. Three items should be measured: high voltage winding to ground, low voltage winding to ground, and high voltage winding to low voltage winding. Here, "ground" refers to the metal shell of the transformer.② Measurement of DC resistance. When a transformer is subjected to short-circuit impact, it often causes winding distortion and deformation. In addition, insulation damage to the transformer winding can lead to turn to turn short circuits, and even phase to phase short circuits. When the winding fails, the distance between turns changes due to overall or local stretching and compression, and the resistance between turns also changes. When measuring, the DC resistance values of the high and low voltage windings of the transformer should be measured separately. According to the relevant regulations on the manufacturing of power transformers, the DC resistance difference between the windings of each phase of transformers above 630KVA should not exceed 2% of the average value of the three phases. For transformers below 630KVA, the phase difference should not exceed 4% of the average value of the three phases, and the line difference should not exceed 2% of the average value of the three phases.③ Measurement of absorption ratio. The insulation condition and moisture content of transformer windings can be determined by measuring the absorption ratio. When measuring, use a stopwatch to measure the time. When the insulation resistance meter reaches the rated speed of 120 revolutions per minute, connect the insulation resistance meter and start timing. Read one value at 15 seconds and another at 60 seconds. The ratio of the two values is the absorption ratio, which should be greater than 1.3. Otherwise, it indicates that the transformer has been affected by moisture or has insulation defects, and a detailed inspection is required.2、 Common faults and causes of high temperature rise in transformersDuring the operation of transformers, their losses mainly include hysteresis and eddy current losses of the iron core, as well as resistance losses of the windings. These losses generate a large amount of heat, which is normally transmitted to the outside through the heat dissipation device, while also causing the temperature of the transformer to rise to a certain extent. After a certain period of time, the transformer should reach a stable temperature rise. If the temperature rise is too high or too fast, or if the temperature rise is significantly higher compared to transformers of the same type and load, it should be considered as a fault. The common causes of high temperature rise in transformers are as follows:1. Local short circuit in the iron core.2. Poor grounding of the iron core.3. Iron yoke screw grounding.4. The power supply voltage is too high.5. Caused by poor contact, looseness, burning out, etc. of the lead part.6. The tap changer has malfunctioned.7. Caused by poor quality in coil manufacturing and maintenance.8. The large burrs and uneven gaps around the core laminations are caused.9. The transformer load is too high.10. Caused by unqualified primary and secondary wiring or poor contact of transformers.3、 Common faults and causes of abnormal output voltage in transformers. Under normal circumstances, the output voltage of transformers should be maintained within a certain range. Low or high voltage is considered a fault phenomenon and should be promptly eliminated. Firstly, the power supply voltage should be checked to see if it is caused by abnormal power supply voltage. If the power supply voltage is high, it can be measured through a transformer. In addition to power supply reasons, there are several common causes of malfunctions, including:1. Caused by short circuit between turns of the winding. This type of fault is often caused by transformer overload or insulation reduction. When a turn to turn short circuit occurs, the transformer will exhibit abnormal output voltage, sometimes accompanied by overheating and abnormal sound.2. It is caused by incorrect gear position of the tap changer. Tap changers are used to regulate voltage. If the gear is incorrect and cannot match the actual power supply voltage, it can cause the output voltage to be too high or too low.3. Caused by unbalanced three-phase load. If the secondary three-phase of the transformer is unbalanced, it will cause changes in the three-phase voltage of the transformer and abnormal output voltage. In severe cases, the phase voltage increases by 1.732 times.4. There is a phase loss on the high-voltage side. Phase loss on the high voltage side can cause serious imbalance in the output voltage on the low voltage side, and even damage to low voltage equipment. There are many reasons for high voltage phase loss, but generally it is caused by inadequate maintenance and other reasons that result in burnt wiring or faults in the old higher-level circuit.In addition, there are also many cases of abnormal secondary voltage output caused by defects in the iron core and winding.

The Necessity of Informationization Construction in the Transformer Industry

2021-04-29

Due to the fact that the main users of transformer manufacturing enterprises are the power sector, many leaders of transformer enterprises believe that as long as they establish good relationships with them, the enterprise can develop and there is no need for information technology construction. This viewpoint of weak information awareness seriously affects the informationization construction of the transformer manufacturing industry, resulting in low level of enterprise information infrastructure management, insufficient investment in informationization construction, and few applications of e-commerce. In fact, the vast majority of transformer manufacturing enterprises have the following problems:(1) The market response is slow, customers often complain, and there are loopholes in marketing. In the information age, the speed of response to rapidly changing markets has become the key to determining a company's competitive advantage. Transformer manufacturing enterprises have a wide variety and specifications. Without establishing a sales information system, it is difficult to handle a large amount of product and customer information to ensure customer satisfaction with pre-sales, in sales, and after-sales services. It is also difficult to manage sales personnel and customers in a timely and effective manner, in order to improve the enthusiasm of sales personnel and reduce loopholes for business personnel to embezzle public funds and individual customers with low reputation to owe or default on accounts.(2) The phenomenon of delayed delivery is common, and the contract fulfillment rate is not high. In recent years, due to the power shortage, the demand for transformers has increased, and the order quantity of transformer manufacturing enterprises has generally increased. But a problem that comes with it is the prominent phenomenon of many companies not delivering goods on time, and the low rate of contract on-time performance. There are reasons for insufficient production capacity, insufficient working capital, and the tight supply of silicon steel sheets in the past two years. In general, delayed delivery is most affected by production capacity. In fact, in many cases, it is not a true lack of production capacity, but rather a lack of balance in production capacity.(3) The level of digital design and manufacturing is relatively low. In design, computer-aided drawing and the use of Excel to calculate electromagnetic schemes are more commonly used, while the use of computer programs for computer-aided design (CAD) is rare. Using 3D CAD design is even less common. Only true CAD can effectively reduce design costs, improve design efficiency, and ensure design quality.(4) Quality problems are common, and the first pass rate of products is low. Due to the imperfect quality system, the IS09001 quality assurance system has not been truly implemented. Except for a few enterprises such as Siemens in Jinan, the vast majority of enterprises have not implemented the Six Sigma quality management method. Therefore, the first pass rate of transformer finished product testing is low, mostly below the Three Sigma quality level, resulting in frequent rework and high quality costs. The defect rate required for the Three Sigma quality level is 0.27%, which means a pass rate of 99.73%. Not to mention the Six Sigma quality level, which requires a defect rate of 3.4 parts per million, almost zero defects.(5) Accounts receivable and inventory occupy a large proportion of funds, and working capital is tight. Due to the impact of rising raw material prices, transformer prices have increased in the past two years, coupled with an increase in order volume, many enterprises have tight working capital. From an internal perspective, many reasons for the tight working capital of enterprises are the high proportion of accounts receivable and inventory occupying funds, resulting in insufficient cash flow.(6) The level of supply management is low, and many transformer manufacturing enterprises have not established good supply relationships, lack win-win thinking, and even basic business procedures are not sound, such as the lack of contracts, resulting in many loopholes in supply work and easily causing losses to the company. Almost none adopt supply chain management. With the help of enterprise informatization, it is possible to fully utilize the resource information of the enterprise, carry out business process restructuring, change the organizational and management mode of the enterprise, introduce modern management concepts, achieve rational and scientific decision-making, and effectively solve the above problems.

Inspection of oil immersed transformers

2021-04-29

1. Monitoring instrumentsThe instruments of the transformer control panel, such as ammeters, voltmeters, power meters, etc., should be read every 1-2 hours and the daily load curve should be drawn. When operating under overload, the meter should be read every 0.5 hours. When the meter is not in the control room, it should be recorded at least twice per shift.2. Monitor the voltage of the transformer power supplyThe variation range of power supply voltage should be within ± 5% of the rated voltage. If the voltage is too high or too low for a long time, the tap changer of the transformer should be adjusted to make the secondary voltage tend to be normal.3. Measure whether the three-phase current is balancedFor transformers with Y and Yn0 connections, the line current should not exceed 25% of the rated current on the low voltage side. If it exceeds this limit, the load on each phase should be adjusted to balance the loads as much as possible.4. Allowable temperature and temperature rise of transformers(1) Allowable temperatureDuring the operation of transformers, copper and iron losses occur, causing the coils and iron cores to heat up. The allowable temperature of a transformer is determined by the heat resistance strength of the insulation material used in the transformer. The insulation of oil immersed power transformers belongs to Class A, and the insulation is made of impregnated organic materials such as paper, wood, and cotton yarn, with an allowable temperature of 105 ℃. The component with the highest temperature in a transformer is the coil, followed by the iron core, and the transformer oil temperature is the lowest. The insulation between coil turns is made of cable paper, and the average temperature of the coil can be measured. Therefore, the temperature of the coil during operation should be ≤ 95 ℃.The operating temperature of power transformers directly affects their output capacity and service life. If the temperature exceeds the allowable value for a long time, the insulation of the transformer is easily damaged and the service life is reduced. The reduction of the service life of transformers can generally be calculated according to the "eight degree rule", that is, when the temperature rises by 8 ℃, the service life is reduced by half. The experiment shows that if the temperature of the hottest point of the transformer winding is maintained at 95 ℃, the transformer can operate continuously for 20 years. If the winding temperature rises to 105 ℃, the service life decreases to 7.5 years. If the winding temperature rises to 120 ℃, the service life decreases to 2.3 years. It can be seen that the service life of a transformer is mainly determined by the operating temperature of the winding.The temperature of transformer winding is related to the load size and ambient temperature. The difference between the temperature of the transformer and the ambient temperature is called the temperature rise of the transformer. For transformers with Class A insulation, when the ambient temperature is 40 ℃ (the highest ambient temperature), the national standard stipulates that the temperature rise of the winding is 65 ℃, and the allowable temperature rise of the upper layer oil temperature is 45 ℃. As long as the upper layer oil temperature and temperature rise do not exceed the specified value, the safe operation of the transformer within the specified service life can be guaranteed.Allowable temperature=Allowable temperature rise+40 ℃When the ambient temperature is above 40 ℃ and heat dissipation is difficult, the transformer is not allowed to operate at full load. When the ambient temperature is less than 40 ℃, although it is beneficial for heat dissipation, the heat dissipation capacity of the coil is limited by structural parameters and cannot be improved, so overloading operation is not allowed. When the ambient temperature is below zero degrees, the transformer is overloaded and the upper oil temperature is maintained below 90 ℃, not exceeding the allowable value of 95 ℃. However, due to the inability to improve the heat dissipation capacity of the coil, the coil temperature rises and heats up, exceeding the allowable value.For example, in an oil immersed self cooling transformer, when the ambient temperature is 32 ℃, the upper oil temperature is 60 ℃, which does not exceed 95 ℃. The temperature rise of the upper oil is 60 ℃ -32 ℃=28 ℃, which is less than the allowable temperature rise of 45 ℃. The transformer can operate normally. If the ambient temperature is 44 ℃ and the upper oil temperature is 99 ℃, although the temperature rise of the upper oil is 99 ℃ -44 ℃=55 ℃, which does not exceed the temperature rise limit, the upper oil temperature exceeds the allowable value, so operation is not allowed. If the ambient temperature is -20 ℃ and the upper oil temperature is 45 ℃, although it is less than 95 ℃, the temperature rise of the upper oil is 45 ℃ - (-20) ℃=65 ℃, which has exceeded the temperature rise limit and is not allowed to operate.Therefore, only when the upper oil temperature and temperature rise value do not exceed the allowable values, can the safe operation of the transformer be guaranteed.5. Operation of Transformer OilCheck the height of the oil level inside the oil pillow and oil filling sleeve, and whether there is any oil leakage at the sealing point. The oil level indicator should generally be at 1/4 to 3/4. Excessive oil level is generally caused by abnormal operation of the cooling device or internal faults in the transformer, resulting in high oil temperature. If the oil level is too low, check whether there is serious oil leakage at each sealing point of the transformer and whether the oil drain valve is tightly closed. The oil color inside the oil gauge tube should be transparent with a slight yellow tint. If it appears reddish brown, it may be caused by dirt on the oil level gauge or by the transformer oil running for too long and the oil temperature being high, resulting in deterioration of the oil quality.

Manufacturing of transformers, rectifiers, and inductors

2021-04-29

Refers to the manufacturing of power electronic equipment such as transformers, static inverters, and transformers.include:Transformers: power transformers, converter transformers, dry-type transformers, box type transformers, electric furnace transformers, test transformers, mining transformers, traction transformers, power transformers, adjustable power transformers, etc;- Transformer auxiliary equipment: transformer on load tap changer, transformer oil cooled water cooler, etc;- General industrial power conversion devices: rectifiers, semiconductor inverters, static frequency converters, stabilized power supplies, stabilized power supplies, uninterruptible power supplies, traction converters, and semiconductor converters for motor speed regulation;- Transformers: voltage transformers, current transformers, combination transformers, etc;- ballasts, reactors, regulators, etc;- Manufacturing of parts for the above-mentioned products.

Overview and Performance Parameters Price of Mining Explosion proof Mobile Substation

2021-04-29

The mining explosion-proof mobile substation (referred to as the mobile substation) consists of mining explosion-proof high-voltage vacuum switches (referred to as high-voltage vacuum switches) for mobile substations, mining explosion-proof dry-type transformers (referred to as dry-type transformers) for mobile substations, and mining explosion-proof low-voltage protection boxes (referred to as low-voltage protection boxes) for mobile substations.The distribution method of KBSGZY mining explosion-proof mobile substation adopts the power supply load of the mobile substation. In case of faults such as short circuit, overload, undervoltage and leakage, the signal feedback is obtained through the low-voltage protection box and sent to the high-voltage vacuum switch to drive the high-voltage side circuit breaker to open. If the dry-type transformer itself fails, it can also be protected by the high-voltage vacuum switch without cutting off the upper level distribution equipment. The high-voltage side of the mobile substation has current, voltage and fault display; Due to the interruption of high voltage, the current is smaller than that of low voltage, overcoming the weakness of the original mobile substation load side fault that can only be protected by the low voltage feeder switch, and the high voltage switch is only an isolation switch. Dry type transformers are required to be explosion-proof for mining, with small volume, low loss, low impedance, and strong ability to withstand short-circuit mechanical forces.The main performance parameters of this product are reasonably selected, which is beneficial for both power supply and product reliability. It is superior to similar foreign products and leads the domestic market, filling the domestic gap and replacing imports.

How to calculate the capacity of power transformers

2021-04-29

The power of a transformer is determined by the load, i.e. P2=U2II2I+U2III2II++ U2nI2In(VA) P1=P2/η(VA)In the formula: Calculation value of secondary power of P2 transformer. Low level power calculation value of P1 transformer.U2I and U2II The voltage (V) of each secondary winding of the transformer is determined by the load.I2I and I2II The current (A) of each secondary winding of the transformer is determined by the load.For transformers with a capacity of less than 1KVA, where the capacity is small and the efficiency is low, η can generally be taken as 0.8 to 0.9. For transformers with a capacity of less than 100VA, the smaller value of η should be selected; Choose the larger value for transformer capacity between 100VA and 1000VA For poor quality silicon steel sheets, an optional value of 0.7 can be chosen.I1=P1/U1 (1.1 to 1.2) (A), where U1 is the low-level voltage (V)1.1 to 1.2 are empirical coefficients considering the no-load excitation current.The capacity of a power transformer is the apparent power S=1.732 × U × I, where s is the apparent power, U is the line voltage, and I is the line current. Due to the presence of inductive and capacitive loads, the power factor of the line cannot be 1, so P=S × 0.8, where p is the active power and 0.8 is the assumed power factor. 4500 ÷ 0.8=5625, so a transformer of 5625KW is needed. However, the manufacturing of transformers is divided by capacity, and it is impossible to manufacture them separately based on your calculation results. Therefore, only the capacity level of 6300KVA can be selected. KVA is the unit of apparent power, and KW is the unit of active power.Here is also an example for everyone:The efficiency of transformer capacity is generally around 0.8. When the load power factor of 500 × 0.8=400 (KW) is 0.8, a 500KVA transformer can normally load 400KW power. As the power factor increases, the load power of the transformer also increases accordingly. The power factor has been increased from 0.7 to 0.95, and for every KW of power, a compensation capacitance of 0.691 kilovolts is required. Therefore, 500 × 0.691 ≈ 346 kilovolts (Kvar)