Abstract: A Schnuerle scavenging two-stroke engine is provided that can keep combustion stability in a wide rotation speed range while suppressing blow-by. The engine of the present invention is a Schnuerle scavenging two-stroke engine (2). A scavenging passage (14(in1)) related to at least one scavenging port (16(in1)) has, at its upper end portion (14a(in1)), an intake-side wall surface (204). The intake-side wall surface (204) defines a first flow direction (42) of scavenging gas discharged from the scavenging port (16(in1)) at a height level of the scavenging port (16(in1)). The upper end portion (14a(in1)) of the scavenging passage (14(in1)) related to the scavenging port (16(in1)) has a guide portion (50) defining a second flow direction (44) of scavenging gas discharged from the scavenging port (16(in1)). The second flow direction (44) is deflected to the intake side from the first flow direction (42) at the height level of the scavenging port (16(in1)).

Abstract: A Schnuerle scavenging two-stroke engine is provided that can keep combustion stability in a wide rotation speed range while suppressing blow-by. The engine of the present invention is a Schnuerle scavenging two-stroke engine (2). A scavenging passage (14(in1)) related to at least one scavenging port (16(in1)) has, at its upper end portion (14a(in1)), an intake-side wall surface (204). The intake-side wall surface (204) defines a first flow direction (42) of scavenging gas discharged from the scavenging port (16(in1)) at a height level of the scavenging port (16(in1)). The upper end portion (14a(in1)) of the scavenging passage (14(in1)) related to the scavenging port (16(in1)) has a guide portion (50) defining a second flow direction (44) of scavenging gas discharged from the scavenging port (16(in1)). The second flow direction (44) is deflected to the intake side from the first flow direction (42) at the height level of the scavenging port (16(in1)).

Abstract: Among multiple scavenging passages 14 included in a cylinder, a scavenging passage connected to at least one scavenging port 16 constitutes a variable scavenging passage 14(ch). An upper end portion of the variable scavenging passage 14(ch) has a guide surface 50 defining a discharge direction of a scavenging gas discharged from a variable scavenging port 16(ch) connected thereto on a horizontal plane. The guide surface 50 includes at least a first guide portion 50(H) defining a first discharge direction of the scavenging gas and a second guide portion 50(L) defining a second discharge direction of the scavenging gas. The discharge direction of the scavenging gas is changed from the first discharge direction to the second discharge direction on the horizontal plane by the first and second guide portions 50(H) and 50(L) in the scavenging stroke.

Abstract: Among multiple scavenging passages 14 included in a cylinder, a scavenging passage connected to at least one scavenging port 16 constitutes a variable scavenging passage 14(ch). An upper end portion of the variable scavenging passage 14(ch) has a guide surface 50 defining a discharge direction of a scavenging gas discharged from a variable scavenging port 16(ch) connected thereto on a horizontal plane. The guide surface 50 includes at least a first guide portion 50(H) defining a first discharge direction of the scavenging gas and a second guide portion 50(L) defining a second discharge direction of the scavenging gas. The discharge direction of the scavenging gas is changed from the first discharge direction to the second discharge direction on the horizontal plane by the first and second guide portions 50(H) and 50(L) in the scavenging stroke.

Abstract: A malware analysis device 10 includes: a dynamic analysis unit 11 which performs dynamic analysis of malware; a communication determination unit 12 which determines whether communication by the malware occurs when the dynamic analysis unit 11 performs dynamic analysis; a static analysis requesting unit 13 which suspends communication when the communication determination unit 12 determines that the communication by the malware occurs to present a request to perform static analysis; and a setting changing unit 14 which sets a device as a communication destination of the malware to make a response obtained by the static analysis as being expected by the malware.

Abstract: A malware analysis device 10 includes: a dynamic analysis unit 11 which performs dynamic analysis of malware; a communication determination unit 12 which determines whether communication by the malware occurs when the dynamic analysis unit 11 performs dynamic analysis; a static analysis requesting unit 13 which suspends communication when the communication determination unit 12 determines that the communication by the malware occurs to present a request to perform static analysis; and a setting changing unit 14 which sets a device as a communication destination of the malware to make a response obtained by the static analysis as being expected by the malware.

Abstract: A malware analysis device 10 includes: a dynamic analysis unit 11 which performs dynamic analysis of malware; a communication determination unit 12 which determines whether communication by the malware occurs when the dynamic analysis unit 11 performs dynamic analysis; a static analysis requesting unit 13 which suspends communication when the communication determination unit 12 determines that the communication by the malware occurs to present a request to perform static analysis; and a setting changing unit 14 which sets a device as a communication destination of the malware to make a response obtained by the static analysis as being expected by the malware.

Abstract: In a carburetor, three downstream body passages in the body communicate with three valve passages in the valve element, and the valve element rotates between a closed position and an opened position. The carburetor is a one-bore type carburetor in which the body passages and the valve passages are respectively partitioned with the body partitions and the valve partitions. When rotating the valve element from the closed position to the opened position, the second body passage and the second valve passage for mixture start to communicate in advance than the first and third body passages and the first and third valve passages for air.

Abstract: To isolate a terminal from a network immediately after a quarantine agent is uninstalled therefrom, a policy readout unit reads out a policy from a policy database and a policy check unit determines whether or not a terminal satisfies the policy that was read out. If it is determined that the terminal satisfies the read out policy, a quarantine server control unit instructs a bridge to destroy a packet with no VLAN tag among the packets sent from the terminal while controlling a quarantine agent to send a packet with a VLAN tag when sending the packet from the terminal.

Abstract: In a carburetor, three downstream body passages in the body communicate with three valve passages in the valve element, and the valve element rotates between a closed position and an opened position. The carburetor is a one-bore type carburetor in which the body passages and the valve passages are respectively partitioned with the body partitions and the valve partitions. When rotating the valve element from the closed position to the opened position, the second body passage and the second valve passage for mixture start to communicate in advance than the first and third body passages and the first and third valve passages for air.

Abstract: To isolate a terminal from a network immediately after a quarantine agent is uninstalled therefrom, a policy readout unit reads out a policy from a policy database and a policy check unit determines whether or not a terminal satisfies the policy that was read out. If it is determined that the terminal satisfies the read out policy, a quarantine server control unit instructs a bridge to destroy a packet with no VLAN tag among the packets sent from the terminal while controlling a quarantine agent to send a packet with a VLAN tag when sending the packet from the terminal.

Abstract: In a two-stroke engine (1) according to the present invention, a piston (6) has a communication passage (28) opened to a crank chamber (10). An air intake port (30) is provided on an inner surface (2a) for causing air to flow into the communication passage (28). After a scavenging port (22) is closed by an outer surface (6a) of the piston (6) moving from the bottom dead center to the top dead center, the communication passage (28) is opened in the outer surface (6a) of the piston so as to communicate with the air intake port (30) and the scavenging port (22).

Abstract: There is provided an air cleaner that is capable of suppressing or reducing malfunctions and problems caused by mixed fuel that back flows from a carburetor, thereby prolonging filter life, reducing filter maintenance frequency, etc. The air cleaner comprises: a fuel accumulation part; and a back flow guide member that guides the mixed fuel that back flows into the air cleaner, wherein the plurality of return flow paths are provided in a radial fashion about the cleaner outlet.

Abstract: There is provided an air cleaner that is capable of suppressing or reducing malfunctions and problems caused by mixed fuel that back flows from a carburetor, thereby prolonging filter life, reducing filter maintenance frequency, etc. The air cleaner comprises: a fuel accumulation part; and a back flow guide member that guides the mixed fuel that back flows into the air cleaner, wherein the plurality of return flow paths are provided in a radial fashion about the cleaner outlet.

Abstract: In a two-stroke engine (1) according to the present invention, a piston (6) has a communication passage (28) opened to a crank chamber (10). An air intake port (30) is provided on an inner surface (2a) for causing air to flow into the communication passage (28). After a scavenging port (22) is closed by an outer surface (6a) of the piston (6) moving from the bottom dead center to the top dead center, the communication passage (28) is opened in the outer surface (6a) of the piston so as to communicate with the air intake port (30) and the scavenging port (22).