Control device of an engine

The invention claimed is: 1. A control system of an engine to control behavior of fuel that is directly injected into a combustion chamber of a cylinder, the control system comprising: a fuel injection valve for directly injecting the fuel into the combustion chamber; and an intake port of the engine for generating a tumble flow in the combustion chamber; and a control device configured to control the fuel injection valve to inject the fuel from the fuel injection valve at a plurality of injection timings including an intake-stroke-early-half injection timing that is set at an early half of an intake stroke of the cylinder and a compression stroke injection timing that is set during a compression stroke of the cylinder, when an operating state of the engine is in a high-load, low-rotation range, wherein the tumble flow is a longitudinal vortex flow of intake air that enters the combustion chamber from the intake port of the engine. 2. The control system of the engine according to claim 1 , wherein the control device is configured to control the fuel injection valve to inject the fuel at a plurality of injection timings including an intake-stroke-latter-half injection timing that is set at a latter half of the intake stroke of the cylinder, when the operating state of the engine is in the high-load, low-rotation range. 3. The control system of the engine according to claim 1 , wherein the control device is configured to control the fuel injection valve to inject the fuel toward a vortex center of the tumble flow at the intake-stroke-early-half injection timing. 4. The control system of the engine according to claim 1 , wherein the fuel injection valve is arranged at an intake port side of a periphery of a ceiling of the combustion chamber and injects the fuel obliquely downward toward an exhaust port side of the engine from the intake port side, and an inclined surface is formed on a piston crown face of the engine to extend obliquely upward toward the fuel injection valve side from a side opposite from the fuel injection valve on the piston crown face. 5. The control system of the engine according to claim 1 , wherein the control device is configured to detect an occurrence of pre-ignition in which an air fuel mixture spontaneously ignites before an ignition timing of the cylinder; and the control system further comprises a variable valve timing mechanism for changing a valve timing of an intake valve of the engine, wherein when pre-ignition is detected by the pre-ignition detection means, the fuel injection valve control means increases the fuel injection amount of the fuel injection valve and the variable valve timing mechanism retards a closing timing of the intake valve to an intake bottom dead center or later. 6. The control system of the engine according to claim 5 , wherein after detecting the pre-ignition, the fuel injection valve maintains the increased fuel injection amount and the variable valve timing mechanism maintains the closing timing of the retarded intake valve until a predetermined number of ignitions are performed. 7. The control system of the engine according to claim 1 , wherein when the operating state of the engine is out of the high-load, low-rotation range, the control device controls the fuel injection valve to inject the fuel at the injection timings including the intake stroke injection timing that is set at the intake stroke of the cylinder, and when the operating state of the engine is in the high-load, low-rotation range, the control device controls the fuel injection valve to inject the fuel at more injection timings than when the operating state of the engine is out of the high-load, low-rotation range. 8. The control system of the engine according to claim 1 , wherein the control device controls the fuel injection valve to inject the fuel in a batch at an intake stroke injection timing, which is set at the intake stroke of the cylinder, when the operating state of the engine is not in the high-load, low-rotation range. 9. The control system of the engine according to claim 1 , wherein the control device controls the fuel injection valve to inject the fuel in a batch at an intake stroke injection timing, which is in a vicinity of a crankshaft angle of 280 degrees before top dead center set in the intake stroke of a cylinder, when the operating state of the engine is not in the high-load, low-rotation range. 10. The control system of the engine according to claim 1 , wherein the control device controls the fuel injection valve to inject the fuel by dividing fuel injection into three timings of the intake-stroke-early-half injection timing, an intake-stroke-latter-half injection timing, and the compression stroke injection timing, when the operating state of the engine in the high-load, low-rotation range. 11. The control system of the engine according to claim 10 , wherein the intake-stroke-early-half injection is set in a vicinity of a crankshaft angle of 300 degrees before top dead center (deg BTDC), the intake-stroke-latter-half injection timing is set in a vicinity of a crankshaft angle of 260 deg BTDC, and the compression stroke injection timing is set in a vicinity of a crankshaft angle of 120 deg BTDC, when the operating state of the engine is in the high-load, low-rotation range. 12. The control system of the engine according to claim 10 , wherein based on an engine speed or a temperature of an engine coolant, when determining that a necessary injection interval for operation of the fuel injection valve cannot be secured if the fuel injection in one cycle is divided into three parts, the control device injects the fuel by dividing the fuel injection into two timings that are the intake-stroke-early-half injection timing and the compression stroke injection timing, when the operating state of the engine is relatively in the high-load, low-rotation range. 13. The control system of the engine according to claim 12 , wherein the intake-stroke-early-half injection timing is set in a vicinity of a crankshaft angle of 300 degrees before top dead center (deg BTDC) and the compression stroke injection timing is set in a vicinity of a crankshaft angle of 120 deg BTDC, when the operating state of the engine is relatively in the high-load, low-rotation range. 14. A control system of an engine to control behavior of fuel that is directly injected into a combustion chamber of a cylinder, the control system comprising: a fuel injection valve for directly injecting the fuel into the combustion chamber; and an intake port of the engine for generating a tumble flow in the combustion chamber; and a control device configured to control the fuel injection valve to inject the fuel from the fuel injection valve at a plurality of injection timings including an intake-stroke-early-half injection timing that is set at an early half of an intake stroke of the cylinder, when an operating state of the engine is in a high-load, low-rotation range, wherein the tumble flow is a longitudinal vortex flow of intake air that enters the combustion chamber from the intake port of the engine; wherein the fuel injection valve is arranged at an intake port side of a periphery of a ceiling of the combustion chamber and injects the fuel obliquely downward toward an exhaust port side of the engine from the intake port side, and an inclined surface is formed on a piston crown face of the engine to extend obliquely upward toward the fuel injection valve side from a side opposite from the fuel injection valve on the piston crown face; and wherein the fuel injection valve is arranged at a slanted angle relative to th