Implementation of capacitor banks: Difference between revisions
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==== Choice of protection, control devices and connecting cables<br> ==== | ====<br> Choice of protection, control devices and connecting cables<br> ==== | ||
The choice of upstream cables and protection and control devices depends on the current loading.<br>For capacitors, the current is a function of: | The choice of upstream cables and protection and control devices depends on the current loading.<br>For capacitors, the current is a function of: | ||
*The applied voltage and its harmonics | *The applied voltage and its harmonics | ||
*The capacitance value | *The capacitance value | ||
The nominal current In of a 3-phase capacitor bank is equal to: <br>with:<br>- Q: kvar rating<br>- Un: Phase-to-phase voltage (kV)<br>The permitted range of applied voltage at fundamental frequency, plus harmonic components, together with manufacturing tolerances of actual capacitance (for a declared nominal value) can result in a 50% increase above the calculated value of current. Approximately 30% of this increase is due to the voltage increases, while a further 15% is due to the range of manufacturing tolerances, so that <br>1.3 x 1.15 = 1.5<br>All components carrying the capacitor current therefore, must be adequate to cover this “worst-case” condition, in an ambient temperature of 50 °C maximum. In the case where temperatures higher than 50 °C occur in enclosures, etc. derating of the components will be necessary. | The nominal current In of a 3-phase capacitor bank is equal to: <br>with:<br>- Q: kvar rating<br>- Un: Phase-to-phase voltage (kV)<br>The permitted range of applied voltage at fundamental frequency, plus harmonic components, together with manufacturing tolerances of actual capacitance (for a declared nominal value) can result in a 50% increase above the calculated value of current. Approximately 30% of this increase is due to the voltage increases, while a further 15% is due to the range of manufacturing tolerances, so that <br>1.3 x 1.15 = 1.5<br>All components carrying the capacitor current therefore, must be adequate to cover this “worst-case” condition, in an ambient temperature of 50 °C maximum. In the case where temperatures higher than 50 °C occur in enclosures, etc. derating of the components will be necessary. | ||
===== Protection ===== | ===== Protection ===== | ||
The size of the circuit-breaker can be chosen in order to allow the setting of long time delay at: | The size of the circuit-breaker can be chosen in order to allow the setting of long time delay at: | ||
*1.36 x In for Classic range<sup>(1)</sup> | *1.36 x In for Classic range<sup>(1)</sup> | ||
*1.50 x In for Comfort range<sup>(1)</sup> | *1.50 x In for Comfort range<sup>(1)</sup> | ||
*1.12 x In for Harmony range<sup>(1)</sup> (tuned at 2.7 f) <sup>(2)</sup> | *1.12 x In for Harmony range<sup>(1)</sup> (tuned at 2.7 f) <sup>(2)</sup> | ||
*1.19 x In for Harmony range<sup>(1)</sup> (tuned at 3.8 f) | *1.19 x In for Harmony range<sup>(1)</sup> (tuned at 3.8 f) | ||
*1.31 x In for Harmony range<sup>(1)</sup> (tuned at 4.3 f) | *1.31 x In for Harmony range<sup>(1)</sup> (tuned at 4.3 f) | ||
Short time delay setting (short-circuit protection) must be insensitive to inrush current. The setting will be 10 x In for Classic, Comfort and Harmony range<sup>(1)</sup> . | Short time delay setting (short-circuit protection) must be insensitive to inrush current. The setting will be 10 x In for Classic, Comfort and Harmony range<sup>(1)</sup> . | ||
'''Example 1 '''<br>50 kvar – 400V – 50 Hz – Classic range | '''Example 1 '''<br>50 kvar – 400V – 50 Hz – Classic range | ||
Long time delay setting: 1.36 x 72 = 98 A<br>Short time delay setting: 10 x In = 720 A | Long time delay setting: 1.36 x 72 = 98 A<br>Short time delay setting: 10 x In = 720 A | ||
| Line 94: | Line 94: | ||
'''Example 2 <br>'''50 kvar – 400V – 50 Hz – Harmony range (tuned at 4.3 f)<br>In = 72 A<br>Long time delay setting: 1.31 x 72 = 94 A<br>Short time delay setting: 10 x In = 720 A | '''Example 2 <br>'''50 kvar – 400V – 50 Hz – Harmony range (tuned at 4.3 f)<br>In = 72 A<br>Long time delay setting: 1.31 x 72 = 94 A<br>Short time delay setting: 10 x In = 720 A | ||
===== Upstream cables ===== | ===== Upstream cables ===== | ||
Figure L34 gives the minimum cross section area of the upstream cable for Rectiphase capacitors. | Figure L34 gives the minimum cross section area of the upstream cable for Rectiphase capacitors. | ||
===== Cables for control ===== | ===== Cables for control ===== | ||
Revision as of 05:42, 5 March 2010
Capacitor elements
Technology
The capacitors are dry-type units (i.e. are not impregnated by liquid dielectric) comprising metallized polypropylene self-healing film in the form of a two-film roll. They are protected by a high-quality system (overpressure disconnector used with a high breaking capacity fuse) which switches off the capacitor if an internal fault occurs.
The protection scheme operates as follows:
- A short-circuit through the dielectric will blow the fuse
- Current levels greater than normal, but insufficient to blow the fuse sometimes occur, e.g. due to a microscopic flow in the dielectric film. Such “faults” often re-seal due to local heating caused by the leakage current, i.e. the units are said to be “self-healing”
- If the leakage current persists, the defect may develop into a short-circuit, and the fuse will blow
- Gas produced by vaporizing of the metallisation at the faulty location will gradually build up a pressure within the plastic container, and will eventually operate a pressure-sensitive device to short-circuit the unit, thereby causing the fuse to blow
Capacitors are made of insulating material providing them with double insulation and avoiding the need for a ground connection (see Fig. L33).
b)
| Electrical characteristics | |||
| Standard | IEC 60439-1, NFC 54-104, VDE 0560 CSA | ||
| Operating range | Rated voltage | 400 V | |
| Rated frequency | 50 Hz | ||
| Capacitance tolerance | - 5% to + 10% | ||
| Temperature range (up to 65 kvar) | Maximum temperature | 55 °C | |
| Average temperature over 24 h | 45 °C | ||
| Average annual temperature | 35 °C | ||
| Minimum temperature | - 25 °C | ||
| Insulation level | 50 Hz 1 min withstand voltage : 6 kV 1.2/50 μs impulse withstand voltage : 25 kV | ||
| Permissible current overload | Classic range(1) | Comfort range(1) | |
| 30% | 50% | ||
| Permissible voltage overload | 10% | 20% | |
Fig. L33:Capacitor element, (a) cross-section, (b) electrical characteristics
Choice of protection, control devices and connecting cables
The choice of upstream cables and protection and control devices depends on the current loading.
For capacitors, the current is a function of:
- The applied voltage and its harmonics
- The capacitance value
The nominal current In of a 3-phase capacitor bank is equal to:
with:
- Q: kvar rating
- Un: Phase-to-phase voltage (kV)
The permitted range of applied voltage at fundamental frequency, plus harmonic components, together with manufacturing tolerances of actual capacitance (for a declared nominal value) can result in a 50% increase above the calculated value of current. Approximately 30% of this increase is due to the voltage increases, while a further 15% is due to the range of manufacturing tolerances, so that
1.3 x 1.15 = 1.5
All components carrying the capacitor current therefore, must be adequate to cover this “worst-case” condition, in an ambient temperature of 50 °C maximum. In the case where temperatures higher than 50 °C occur in enclosures, etc. derating of the components will be necessary.
Protection
The size of the circuit-breaker can be chosen in order to allow the setting of long time delay at:
- 1.36 x In for Classic range(1)
- 1.50 x In for Comfort range(1)
- 1.12 x In for Harmony range(1) (tuned at 2.7 f) (2)
- 1.19 x In for Harmony range(1) (tuned at 3.8 f)
- 1.31 x In for Harmony range(1) (tuned at 4.3 f)
Short time delay setting (short-circuit protection) must be insensitive to inrush current. The setting will be 10 x In for Classic, Comfort and Harmony range(1) .
Example 1
50 kvar – 400V – 50 Hz – Classic range
Long time delay setting: 1.36 x 72 = 98 A
Short time delay setting: 10 x In = 720 A
Example 2
50 kvar – 400V – 50 Hz – Harmony range (tuned at 4.3 f)
In = 72 A
Long time delay setting: 1.31 x 72 = 94 A
Short time delay setting: 10 x In = 720 A
Upstream cables
Figure L34 gives the minimum cross section area of the upstream cable for Rectiphase capacitors.
Cables for control
The minimum cross section area of these cables will be 1.5 mm2 for 230 V.
For the secondary side of the transformer, the recommended cross section area is u 2.5 mm2.
| Bank power (kvar) | Copper cross- section (mm2) | Aluminium cross- section (mm2) | |
| 230 V | 400 V | ||
| 5 | 10 | 2.5 | 16 |
| 10 | 20 | 4 | 16 |
| 15 | 30 | 6 | 16 |
| 20 | 40 | 10 | 16 |
| 25 | 50 | 16 | 25 |
| 30 | 60 | 25 | 35 |
| 40 | 80 | 35 | 50 |
| 50 | 100 | 50 | 70 |
| 60 | 120 | 70 | 95 |
| 70 | 140 | 95 | 120 |
| 90-100 | 180 | 120 | 185 |
| 200 | 150 | 240 | |
| 120 | 240 | 185 | 2 x 95 |
| 150 | 250 | 240 | 2 x 120 |
| 300 | 2 x 95 | 2 x 150 | |
| 190-210 | 360 | 2 x 120 | 2 x 185 |
| 245 | 420 | 2 x 150 | 2 x 240 |
| 290 | 480 | 2 x 185 | 2 x 300 |
| 315 | 540 | 2 x 240 | 3 x 185 |
| 350 | 600 | 2 x 300 | 3 x 240 |
| 385 | 660 | 3 x 150 | 3 x 240 |
| 420 | 720 | 3 x 185 | 3 x 300 |
Fig L34: Cross-section of cables connecting medium and high power capacitor banks(1)
