Fuel system and corresponding method

The invention claimed is: 1. Fuel system for supplying pressurised low viscosity fuel to an internal combustion engine, the fuel system comprising a low pressure fuel system, a high-pressure fuel pump, a common rail, at least one fuel injector, and an engine management system, the high-pressure fuel pump is arranged to supply pressurised fuel to the common rail, and the common rail is arranged to supply high-pressure fuel to the at least one fuel injector, which is configured to inject high-pressure fuel into a combustion chamber of the combustion engine, wherein the engine management system is arranged to initiate a recirculating cooling fuel flow through at least the high-pressure fuel pump for avoiding fuel boiling by means of either increasing the target pressure of the fuel within the common rail above a threshold level, which triggers opening a high-pressure fuel relief valve that is arranged, downstream of the high-pressure fuel pump, such that at least part of the fuel supplied by the high-pressure fuel pump is returned to the low pressure fuel system via the high-pressure fuel relief valve, or providing increased internal fuel leakage within the at least one fuel injector, such that at least part of the fuel supplied by the high-pressure fuel pump is returned to the low pressure fuel system by a return line. 2. Fuel system according to claim 1 , wherein the engine management system is arranged to, upon determining a risk of fuel boiling within the high-pressure fuel pump, initiate the recirculating cooling fuel flow through the high-pressure fuel pump. 3. Fuel system according to claim 1 , wherein the engine management system is configured to determine that there is a risk of fuel boiling within the high-pressure fuel pump when the engine is operated in a fuel non-injection mode. 4. Fuel system according to claim 1 , wherein the engine management system is configured to determine the risk of fuel boiling within the high-pressure fuel pump based on at least one of the following parameters: engine operation mode, duration of the engine operation mode, fuel temperature adjacent and/or within the high-pressure fuel pump, fuel pressure adjacent and/or within the high-pressure fuel pump, fuel boiling point. 5. Fuel system according to claim 1 , wherein the high-pressure fuel relief valve is a mechanical relief valve, which preferably is arranged along a fuel supply line between the high-pressure fuel pump and the common rail, or connected to the common rail. 6. Fuel system according to claim 1 , wherein the high pressure fuel relief valve also functions as a safety pressure limiting relief valve of the fuel system for preventing damages to any of the common rail, the at least one fuel injector, or the high-pressure fuel pump due to excessive fuel pressure. 7. Fuel system according to claim 1 , wherein the high-pressure fuel relief valve is the single relief valve downstream of the high-pressure fuel pump and upstream of the at least one fuel injector. 8. Fuel system according to claim 1 , wherein the fuel system further comprises an additional safety relief valve ( 32 ) arranged downstream of the high-pressure fuel pump and upstream of the at least one fuel injector, wherein the threshold level that triggers opening the high-pressure fuel relief valve is lower than the threshold level that triggers opening of the additional safety relief valve ( 32 ). 9. Fuel system according to claim 1 , wherein the temporarily increased internal fuel leakage within the at least one fuel injector is provided by increasing valve control leakage within the at least one fuel injector. 10. Fuel system according to claim 9 , wherein the valve control leakage within the at least one fuel injector is increased by allowing inlet of fuel from the common rail to an internal injector volume ( 33 ) of the at least one fuel injector, while simultaneously and/or subsequently allowing discharge of fuel from the internal injector volume ( 33 ) to the return line, wherein the inlet and discharge of fuel is directly or indirectly controlled by the engine management system such that no fuel is injected into the combustion chamber ( 11 ). 11. Fuel system according to claim 10 , wherein the at least one fuel injector comprises: a spring-loaded nozzle ( 11 ) for injecting high-pressure fuel into the combustion chamber; an inlet valve ( 10 ) arranged on a fuel supply line ( 35 ) connecting the nozzle ( 11 ) with the common rail, which inlet valve ( 10 ) is directly or indirectly controlled by the engine management system; and a spill valve ( 12 ) arranged on a fuel return line connecting the low pressure fuel system with the fuel supply line ( 35 ) between the inlet valve ( 10 ) and the nozzle ( 11 ), which fuel spill valve ( 12 ) is directly or indirectly controlled by the engine management system; wherein the inlet of fuel is controlled by the inlet valve ( 10 ), and the discharge of fuel is controlled by the spill valve ( 12 ), and wherein during the time of temporarily increased internal fuel leakage within the at least one fuel injector the inlet valve ( 10 ) and spill valve ( 12 ) are controlled such that the fuel pressure within the internal injector volume ( 33 ) is not exceeding a threshold level that triggers opening of the nozzle ( 11 ), thereby preventing fuel from being injected into the combustion chamber. 12. Fuel system according to claim 10 , wherein the temporarily increased internal fuel leakage within the at least one fuel injector is provided by means of a series of short duration control pulses from the engine management system for providing repeated short duration inlet of fuel into the internal injector volume 33 ) and discharge of fuel from the volume ( 33 ). 13. Fuel system according to claim 10 , wherein the temporarily increased internal fuel leakage within the at least one fuel injector is configured to be realised also during engine injecting operation mode by scheduling the inlet and discharge of fuel between time periods of normal inlet and discharge of fuel associated with the engine injecting operation mode. 14. Method for providing a recirculating cooling fuel flow through at least a high-pressure fuel pump, wherein the high pressure fuel pump is part of a fuel system that is configured to supply pressurised low viscosity fuel, in particular dimethyl ether (DME) or a blend thereof, to an internal combustion engine, in particular a compression ignition engine, the fuel system comprising a low pressure fuel system, a high-pressure fuel pump, a common rail, at least one fuel injector, and an engine management system, wherein the high-pressure fuel pump is arranged to supply pressurised fuel to the common rail, and wherein the common rail is arranged to supply high-pressure fuel to the at least one fuel injector, which is configured to inject high-pressure fuel into a combustion chamber of the combustion engine, the method comprising: initiating a recirculating cooling fuel flow through at least the high-pressure fuel pump for avoiding fuel boiling by means of either increasing the target pressure of the fuel within the common rail above a threshold level that triggers opening a high-pressure fuel relief valve that is arranged downstream of the high-pressure fuel pump, such that at least part of the fuel supplied by the high-pressure fuel pump is returned to the low pressure fuel system via the high-pressure fuel relief valve, or providing increased internal fuel leakage within the at least one fuel injector, such that at least part of the fuel supplied by the high-pressure fuel pump is returned to the low pressure fuel system by a return line.