Engine configured to drive a diaphragm fuel pump using pressure fluctuation in a crank chamber of the engine

The invention claimed is: 1. An engine having a structure of a four-stroke engine, the engine comprising: a piston configured to reciprocally move; a crank chamber in which pressure fluctuation occurs by the piston moving reciprocally in the crank chamber; a carburetor including a diaphragm fuel pump, the diaphragm fuel pump including: a pump chamber configured to suck in and eject fuel; and a diaphragm chamber to which a pressure that drives the pump chamber is supplied; a single communicating path configured to allow communication between the diaphragm chamber and the crank chamber; and an opening of the communicating path in the crank chamber side, the opening being formed near a position in which a termination portion of a skirt part of the piston is located when the piston is located at a top dead center such that the piston opens and closes the opening, wherein the piston closes the opening of the communicating path when a positive pressure is created in the crank chamber and opens the opening to supply substantially only a negative pressure from the crank chamber to the diaphragm chamber via the communicating path, and the opening is not open in a combustion chamber formed by a cylinder part and an upper portion of the piston. 2. The engine according to claim 1 , wherein an atmospheric pressure opening path configured to communicate with a space under atmospheric pressure is connected to the communicating path. 3. The engine according to claim 1 , wherein an atmospheric pressure opening path configured to communicate with a space under atmospheric pressure is connected to the diaphragm chamber. 4. The engine according to claim 1 , wherein the opening of the communicating path in the crank chamber side is formed in a position closer to a crankshaft than a position in which a piston ring is located when the piston is located at a bottom dead center. 5. The engine according to claim 4 , wherein the opening of the communicating path in the crank chamber side is formed in a position near the position in which the piston ring of the piston is located when the piston is located at the bottom dead center. 6. The engine according to claim 1 , further comprising a communicating path configured to allow communication between the diaphragm chamber and the crank chamber, wherein an orifice is formed in an opening of the communicating path in the crank chamber side. 7. The engine according to claim 1 , further comprising a communicating path configured to allow communication between the diaphragm chamber and the crank chamber, wherein an orifice is formed in an atmospheric pressure opening path, the atmospheric pressure opening path being connected to one of the communicating path and the diaphragm chamber to allow communication with a space under atmospheric pressure. 8. The engine according to claim 1 , further comprising a communicating path configured to allow communication between the diaphragm chamber and the crank chamber, wherein an atmospheric pressure opening path opens in a cleaned side of an air cleaner, the atmospheric pressure opening path being connected to one of the communicating path and the diaphragm chamber to allow communication with a space under atmospheric pressure. 9. The engine according to claim 1 , wherein the opening of the communicating path in the crank chamber side is closed by the piston when a positive pressure is created in the crank chamber.