Shore power
Table 2 – Typical system requirements for different ship types and sizes
Power shore hidrosilindirli dayaqlar
The equipment can operate with ship power generator off, or with ship power generator on by seamless transfer.
It has standard safety protection system such as reverse-power protect and high overload ability.
Voltage closed-loop control, output voltage can keep stable when the load is abrupt
Patented VSV technology, can be used as SVG for reactive power compensation of port power distribution when idle
The only one Chinese Company who passed the SIL2 certification in this industry.
NC AMP L series shore Power
Output Voltage: 380V, 690V
Rated capacity: 100-8000kva
Main features
Modular design, Power cell parallel connection, no need reactor
Rectifier can choose diode type or IGBT PWM
The equipment can operate with ship power generator off, or with ship power generator on by seamless transfer.
It has standard safety protection system such as reverse-power protect and high overload ability.
Voltage closed-loop control, output voltage can keep stable when the load is abrupt
| NC AMP H series shore power | ||
| Input | Voltage | 3P,3-10KV |
| Frequency | 50HZ/60HZ +/- 10% | |
| Allowable voltage fluctuation range | +/-20% | |
| Output | Voltage | 6kv,6.6kv (others for option) |
| Frequency | 50hz/ 60hz | |
| Overload capacity | 120% 1min | |
| waveform | Multi-level PWM, sine wave | |
| Performance | Input | THDi |
| Output | THDU | |
| Efficiency | >= 98% | |
| Power factor | >0.96 (rated capacity) | |
| MTTF | >50000Hours | |
| Working condition | Enviorment | Indoor or outdoor with containerized cabinet |
| Temperature | -15 – 40℃ | |
| Humidity | 95% without condensation | |
| Control | Control method | constant frequency & voltage output, voltage close loop |
| frequency resolution | 0.01hz | |
| Fieldbus | Profibus, Modbus… | |
| Others | Protections | over-voltage, over-current, overloading, transformer overheating, grouding error, fan error, safty lock |
| Protection level | IP31, others for option | |
| Noise level | ||
| Cooling system | Air/ water | |
| Options | Containerized cabinet, output isolation transformer, junction box, bypass cabinet | |
| NC AMP L series shore power | ||
| Input | Voltage | 3P,380-690V |
| Frequency | 50HZ/60HZ +/- 10% | |
| Allowable voltage fluctuation range | +/-10% | |
| Output | Voltage | 440V (others for option) |
| Frequency | 50hz/ 60hz | |
| Overload capacity | 120% 1min | |
| Performance | Input | THDi |
| Efficiency | >= 97% | |
| Power factor | >0.95 (rated capacity) | |
| MTTF | >50000Hours | |
| Working condition | Enviorment | Indoor or outdoor with containerized cabinet |
| Temperature | -15 – 40℃ | |
| Humidity | 95% without condensation | |
| Control | Control method | constant frequency & voltage output, voltage close loop |
| frequency resolution | 0.01hz | |
| Fieldbus | Profibus, Modbus… | |
| Others | Protections | Short circuit, overvoltage,overcurrent,overloading, undervoltage, phase lose, overheating |
| Protection level | IP11, others for option | |
| Noise level | ||
| Cooling system | Air cooled | |
| Options | Containerized cabinet, output isolation transformer, junction box, bypass cabinet |
Shore power
When a ship docks, it no longer needs energy for propulsion. However, ships may still be large consumers of energy when stationary as several of the ship functions are still operating. This includes ventilation/heating/cooling, pumps, control systems and cargo handling systems. Consequently, the generators are running when in port, resulting in local noise and air emissions as well as global climate driving emission. Rather than letting the generators on board make the electricity this can come from shore power.
Applicability and assumptions
Pawanexh Kohli (Own work) [CC BY-SA 3.0 or GFDL, via Wikimedia Commons]
Shore power can be installed for all types of vessel and for all ages with need for power in harbour, and has been used for years especially for smaller vessels, but also some larger passenger vessels.
For smaller vessels to draw power from the land based mains supply when docked is not a new phenomenon. Shore power has been used extensively for many years for vessels with moderate power requirements; typically less than 50 to 100 kW. These vessels are capable of making use of normal grid voltage and frequency, and replace the energy from the generators with the shore power with only marginal investments.
For the larger vessels with higher power requirements (100 kW up to 10 to 15 MW) it gets a bit more complicated. To serve these vessels with shore power, dedicated and relatively costly installations are required, both on land and on board the vessels. This may include upgrading the grid capacity, frequency converters and complex high power connectors. Consequently, relatively few vessels and ports are capable of making use of shore power, even though the environmental upsides are considerable. Still, cold ironing may be regarded as a mature technology that has been in regular use since the 1980s.
Shore power may potentially eliminate the local noise and air pollution related to ship activity in a port. Depending on the energy source, it may also contribute positively to the climate driving effects of ship operation, but as an isolated initiative, it is generally not considered to be among the most cost effective climate initiatives.
On the land side, the high power cold ironing system consists of the following:
- High voltage grid to the port
- Frequency and voltage convertors/transformers
- Control panels and connection boxes
- Cable reel and connectorsOn the ship side the following will have to be installed:
- The grid power solution and the frequency converters typically represent the costliest elements on the shore side. Depending on the availability of grid power and the power requirements, the cost of installing shore power on the shore side will vary considerably.
- Transformer
- Power distribution system
- Control panel
- Frequency converter (optional for greater flexibility)
- Connectors and cable reel (optional for greater flexibility)
Table 1 – Typical system specs for the different power requirements
| Power Capacity | Typical spec |
| 230/400/440V – 50/60hz | |
| 100 – 500kW | 400/440/690V – 50/60hz |
| 500-1000kW | 690V/6.6/11kV – 50/60hz |
| >1MW | 6.6/11kV – 50/60hz |
Table 2 – Typical system requirements for different ship types and sizes
| Vessel types | 1000 – 4999 GT | 5000 – 9999 GT | 10000 – 24999 GT | 25000 – 49999 GT | 50000 – 99999 GT | >= 100000 GT | |
| Oil tankers | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz |
| Chemical/product tankers | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | ||
| Gas tankers | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz |
| Bulk carriers | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | |
| General cargo | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | ||
| Containers vessels | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | |
| Ro Ro vessels | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | |
| Reefers | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | |||
| Passengers vessels | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz |
| Offshore supply vessel | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 6.6/11kV – 50/60hz | ||||
| Other offshore service vessels | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz | 690V/6.6/11kVV – 50/60hz |
| Other activities | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 690V/6.6/11kVV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz | 6.6/11kV – 50/60hz |
| Fishing vessels | 230/400/440V – 50/60hz | 400/440/690V – 50/60hz | 6.6/11kV – 50/60hz |
Cost of implementation
Table 3 – Estimated cost for implementing shore power on board vessels
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