วันอาทิตย์ที่ 3 กรกฎาคม พ.ศ. 2554

Monitoring of Transformers

As a vital part of transmission and distribution systems, transformers are built and foreseen, to be unfailingly reliable. Nevertheless, internal faults like partial discharges can occur, and the question with such faults is that if left un-corrected, they can finally morph into catastrophic faults that can result in power outages and even end-user property damage.

Transformer Monitoring: What's Involved

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* Data acquisition
* Sensor development
* Data analysis
* amelioration of links in the middle of measurements and failures

Easily Prevented

Preventing disasters of this nature is really quite simple, and involves transformer monitoring. Monitoring transformers and spotting problems before they turn into unmanageable incidents can preclude faults that are high-priced to fix and may result in a loss of service. Transformer monitoring in general involves data acquisition, sensor development, data analysis, and the amelioration of causal links in the middle of measured values and failures of transformers.

Installing monitoring equipment on transformers is usually done for two reasons:

1. Monitoring important transformer functions can help detect developing faults before they lead to a catastrophic failure
2. Monitoring transformer functions can allow for a turn from periodic to condition-based maintenance

Monitoring Equipment

Monitoring equipment is constantly mounted on the transformer and is online 24/7. Reliable, low-cost monitoring is thus a essential condition. Failure rates of transformers are usually low (0.2 - 2% per transformer/year), and high-cost failure stoppage systems cannot thus be justified, especially when redundancy is ready and the consequential costs are thus limited. To keep within this cost barrier, some compromise on the functionality of the
monitoring equipment is necessary.

Transformer Monitoring: Parameters

* Oil temperature
* Moisture levels
* execution of cooling fans
* Electrical load levels

In a majority of cases, it is enough to provide a reliable warning signal without online prognosis and diagnosis, in case,granted that hand-operated or automatic diagnostic methods are ready to result up the alarm. Specifically with regard to power distribution networks in the Us, a majority of the transformer population is aging, and most emerging faults can be foreseen, from these units.Monitoring equipment should thus be designed for field facility on operational transformers that might date back a few decades.

Detection of Developing Faults

The main transformer parts that need monitoring are insulation quality, winding temperatures, oil quality, and mechanical challenging parts such as on-load tap changers (Oltc). Monitoring the windings and insulation systems for gas-in-oil and partial extraction are crucial; climatic characteristic and load monitoring on the other hand, is regarded as base data and should be included in any type of transformer monitoring.

Oltc failures are typically caused by mechanical faults with bearings, springs, shafts and drive mechanisms, intimately followed by electrical faults such as burnt transition resistors, choked contacts, and insulation problems.

Some parameters of transformer monitoring, and the sensors best applicable are discussed below:

* Dissolved Gas prognosis (Dga)

An established diagnostic method, gas-in-oil prognosis involves analyzing the types, concentration and output rates of generated gases. Dissimilar types of gases are produced based on the types of faults; for example, overheated cellulose leads to the formation of carbon oxides, but arcing leads to the generation of acetylene.

Depending on the criticality of each unit, oil samples are taken manually at quarterly intervals (between 12 and 24 months) and the gasses are extracted from these samples. On-line gas sensors are typically the first choice in designing full time monitoring systems for Dga; plainly because the technique of prognosis is well established and accepted, and the sensor is truly capable of detecting a wide range of failure types.

Partial Discharges (Pd)

Partial extraction testing of de-energized transformers is a essential tool for assessment of widespread transformer integrity, however, on-line, real

time, partial extraction monitoring is, in general, more high-priced and complicated. For example, glass fiber rods acting as wave-guides inside the main tank have been applied to large transformers, but the cost and complexity of facility has made such a system unsuitable for online monitoring.

There are any advantages associated with electrical Pd monitoring, but it has been difficult to construct field applications thanks to the difficulties in separating internal and external Pd sources. Sensors that are being tested and advanced currently include externally fitted acoustical sensors, which are more cost-effective but are susceptible to disturbances from rough outdoor substation environments.

* climatic characteristic
The load potential of a transformer is little by the hot spot of the windings. The hot spot is typically calculated indirectly from measurements of oil temperatures and load current. An alternative formula involves fiber-optic climatic characteristic sensors that are installed in the winding during the manufacturing process. These sensors come in two varieties - fibers which quantum the climatic characteristic at a singular point, and distributed fibers that quantum the climatic characteristic along their length. All of these systems involve high costs; in particular, the distributed fiber sensor is the most high-priced to install and can only be applied to new transformers.

New Techniques

The condition of the insulation can be judged from other parameters as well, such as moisture levels and particulate content. Data interpretation with these parameters is not straightforward, but new techniques are being advanced using software to analyze the large body of historical data ready and recognize patterns of progression towards failure. If similar deterioration is detected for a transformer in service, healthful operation can be taken.

Other types of online sensors have also been investigated. Examples of such systems are online measurements of the moisture article of the oil, static payment in oil, optical sensors and pump monitoring.

Also on-line measurements of the moisture in the cellulose by optical fiber techniques are being studied. In general, these systems do not have a strong coupling to important and frequent failure modes.

Monitoring of Transformers

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