3588753 Volvo.Penta Exhaust bellows

Turbocharger
A turbocharger increases the temperature and the density of the air that is sent to the engine cylinder. This condition causes a lower temperature of ignition to develop earlier in the compression stroke. The compression stroke is also timed in a more accurate way with the fuel injection. Surplus air lowers the temperature of combustion. This surplus air also provides internal cooling.A turbocharger improves the following aspects of engine performance:
Power output is increased.
Engine torque is increased.
Engine efficiency is increased.
Illustration 1 g00302786
Components of a turbocharger (typical example)
(1) Air intake
(2) Compressor housing
(3) Compressor wheel
(4) Bearing
(5) Oil inlet port
(6) Bearing
(7) Turbine housing
(8) Turbine wheel
(9) Exhaust outlet
(10) Oil outlet port
(11) Exhaust inlet A turbocharger is installed between the exhaust and intake manifolds. The turbocharger is driven by exhaust gases which flow through the exhaust inlet (11). The energy of the exhaust gas turns the turbine wheel (8). Then, the exhaust gas flows out of the turbine housing (7) through the exhaust outlet (9).Turbine wheel (8) and compressor wheel (3) are installed on the same shaft. Therefore, turbine wheel (8) and compressor wheel (3) rotate at the same rpm. The compressor wheel is enclosed by compressor housing (2). The compressor wheel compresses the intake air. The intake air flows into the engine cylinders through the inlet valves of the cylinders.The oil from the main gallery of the cylinder block flows through the oil inlet port (5) in order to lubricate the turbocharger bearings (4) and (6). The pressurized oil passes through the bearing housing of the turbocharger. The oil is returned through the oil outlet port (10) to the oil pan.The turbocharger has a wastegate. The wastegate is controlled by the boost pressure. This allows some of the exhaust gases to bypass the turbine wheel at higher engine speeds. The wastegate is a type of flapper valve that automatically opens at a preset level of boost pressure in order to allow exhaust gas to flow around the turbine. The wastegate allows the design of the turbocharger to be more effective at lower engine speeds.NOx Reduction System (NRS)
Illustration 2 g03789285
Typical example
The NOx Reduction System (NRS) operates with the transfer of the hot exhaust gas from the exhaust manifold to the exhaust gas cooler (3). The hot exhaust gas is cooled in the exhaust gas cooler. The now cooled exhaust gas passes through the assembly of the exhaust gas valve to an electronic controlled valve (1). The electronically controlled valve is electronically actuated. The valve and inlet gas throttle valve (2) are controlled by the Electronic Control Module (ECM).The butterfly valve that is located in the exhaust gas valve (NRS) has two main functions. The first function is to prevent the reverse flow of charge air from the inlet side of the engine to the exhaust side of the engine. The second function of the reed valve is to obtain exhaust gas when the peak exhaust pressure is above the average inlet pressure.The electronically controlled valve (1) opens to allow the flow of cooled exhaust gas from the exhaust gas cooler (3) to mix with the air flow from the inlet. The mixing of the cooled exhaust gas and the air flow from the inlet reduces the oxygen content of the gas mixture. This results in a lower combustion temperature, so decreases the production of NOx.In some instances, the engine will need to use the electronically controlled exhaust gas valve (1) and the inlet gas throttle valve (2) for the NOx Reduction System (NRS) in order to generate the required flow of exhaust gas. The inlet gas throttle valve for the NOx Reduction System (NRS) works by reducing the pressure in the inlet manifold in order to draw through extra exhaust gas.Cylinder Head And Valves
Illustration 3 g00905459
Cross section of the inlet and exhaust valves in the cylinder head (typical example)
Illustration 4 g00905464
Cylinder head and valves (typical example)
(1) Collets
(2) Valve spring retainer
(3) Valve spring
(4) Valve seal
(5) Valve guide
(6) Cylinder head
(7) Cylinder head gasket
(8) Pushrod
(9) Lifter
(10) Exhaust valve
(11) Inlet valve The valves and the rocker shaft assembly control the flow of air into the cylinders and out of the cylinders during engine operation. The cylinder head assembly has two valves for each cylinder. Each valve has one valve spring (3). The ports for inlet valve (11) and exhaust valve (10) are on the left side of the cylinder head.The valve moves along a steel valve guide (5). The valve guides can be replaced.The inlet valve and the exhaust valve are opened and closed by the rotation and movement of the following components:
Crankshaft
Idler gear
Camshaft
Valve lifters
Pushrods
Rocker arms
Valve springsThe camshaft gear is driven by the idler gear. The camshaft gear, the idler gear, and the crankshaft gear are timed together. When the camshaft turns, the valve lifters are moved up and down. The pushrods move the rocker arms. The rocker arms make the inlet valves and the exhaust valves open and close. This is in sequence with the firing order of the engine. The valve springs force the valves back to the closed position.Crankcase Breather
The crankcase breather gases are part of the engines measured emissions output. Any tampering with the breather system could invalidate the engines emissions compliance.
The engine has a low-pressure closed circuit breather system installed.The valve mechanism cover contains a closed breather assembly. The breather is sealed from the outside air by a diaphragm. The gases in the valve cover, which are caused by blowby, pass from the crankcase to the next component depending on the type of aspiration system the engine has.The crankcase gas is routed through an external pipe from the valve mechanism cover to t