A carburetor has a carburetor body wherein an intake channel is formed. A throttle flap is pivotably mounted by a throttle shaft in the carburetor body for controlling the free flow cross-section of the intake channel. The intake channel has a first longitudinal center axis in the region of the throttle shaft. The throttle flap has first and second end positions, wherein the throttle flap opens a larger flow cross-section of the intake channel in the second end position than in the first end position. A partition wall section, on which the throttle flap lies in the second end position, is arranged upstream of the throttle shaft. A choke flap is upstream of the partition wall section and is pivotable between first and second end positions. In their second end positions, the throttle flap and the choke flap overlap in the direction of the first longitudinal center axis.

A carburetor has a carburetor body wherein an intake channel is formed. A throttle flap is pivotably mounted by a throttle shaft in the carburetor body for controlling the free flow cross-section of the intake channel. The intake channel has a first longitudinal center axis in the region of the throttle shaft. The throttle flap has first and second end positions, wherein the throttle flap opens a larger flow cross-section of the intake channel in the second end position than in the first end position. A partition wall section, on which the throttle flap lies in the second end position, is arranged upstream of the throttle shaft. A choke flap is upstream of the partition wall section and is pivotable between first and second end positions. In their second end positions, the throttle flap and the choke flap overlap in the direction of the first longitudinal center axis.

A carburetor has a carburetor body wherein an intake channel is formed. A throttle flap is pivotably mounted by a throttle shaft in the carburetor body for controlling the free flow cross-section of the intake channel. The intake channel has a first longitudinal center axis in the region of the throttle shaft. The throttle flap has first and second end positions, wherein the throttle flap opens a larger flow cross-section of the intake channel in the second end position than in the first end position. A partition wall section, on which the throttle flap lies in the second end position, is arranged upstream of the throttle shaft. A choke flap is upstream of the partition wall section and is pivotable between first and second end positions. In their second end positions, the throttle flap and the choke flap overlap in the direction of the first longitudinal center axis.

A carburetor has a carburetor body wherein an intake channel is formed. A throttle flap is pivotably mounted by a throttle shaft in the carburetor body for controlling the free flow cross-section of the intake channel. The intake channel has a first longitudinal center axis in the region of the throttle shaft. The throttle flap has first and second end positions, wherein the throttle flap opens a larger flow cross-section of the intake channel in the second end position than in the first end position. A partition wall section, on which the throttle flap lies in the second end position, is arranged upstream of the throttle shaft. A choke flap is upstream of the partition wall section and is pivotable between first and second end positions. In their second end positions, the throttle flap and the choke flap overlap in the direction of the first longitudinal center axis.

A fuel bowl is disclosed. The fuel bowl comprises a body having an interior opposite an exterior, four sides, and a bottom opposite an opening. The opening is configured to be in fluid communication with a carburetor or an adaptor. The fuel bowl also comprises a fuel inlet port disposed in at least one of the four sides and configured to receive a gaseous fuel from a fuel regulator. The gaseous fuel expands and contracts within the body. A carburetor system is also disclosed. The carburetor system comprises a gaseous fuel, a fuel regulator configured to receive and deliver the gaseous fuel, a fuel bowl in fluid communication with the fuel regulator and a carburetor, a final fuel metering restriction disposed in an inlet supply port of a cylinder of the carburetor, and a venturi disposed in the carburetor.

An external idle air bypass for carbureted engines having a threaded housing containing a ball valve, which mounts to the outside of the carburetor at a passage which admits air to the intake plenum beneath the carburetor's throttle blades. The threaded housing may be made of metal or other materials. The ball valve may be made from brass and steel, though other materials can be used. A handle is used to operate the ball valve and is retained by a threaded nut. An air cleaner may be attached to the valve housing. Opening and closing the ball valve permits a precisely metered amount of air to enter the engine at idle, enabling the mechanic to vary the amount and air/fuel ratio of the engine without disturbing the throttle blades.

An external idle air bypass for carbureted engines having a threaded housing containing a ball valve, which mounts to the outside of the carburetor at a passage which admits air to the intake plenum beneath the carburetor's throttle blades. The threaded housing may be made of metal or other materials. The ball valve may be made from brass and steel, though other materials can be used. A handle is used to operate the ball valve and is retained by a threaded nut. An air cleaner may be attached to the valve housing. Opening and closing the ball valve permits a precisely metered amount of air to enter the engine at idle, enabling the mechanic to vary the amount and air/fuel ratio of the engine without disturbing the throttle blades.

A carburetor with a throttle valve is provided in which a linkage member is in communication with the throttle valve. An idle down handle can be moved from an unactuated position to an actuated position and is in communication with the throttle valve. Movement of the idle down handle to the actuated position causes the throttle valve to be placed into the closed position. When the idle down handle is in the unactuated position the throttle linkage member can cause the throttle valve to be moved back and forth between the open and closed positions.

A carburetor with a throttle valve is provided in which a linkage member is in communication with the throttle valve. An idle down handle can be moved from an unactuated position to an actuated position and is in communication with the throttle valve. Movement of the idle down handle to the actuated position causes the throttle valve to be placed into the closed position. When the idle down handle is in the unactuated position the throttle linkage member can cause the throttle valve to be moved back and forth between the open and closed positions.

A carburetor with a throttle valve is provided in which a linkage member is in communication with the throttle valve. An idle down handle can be moved from an unactuated position to an actuated position and is in communication with the throttle valve. Movement of the idle down handle to the actuated position causes the throttle valve to be placed into the closed position. When the idle down handle is in the unactuated position the throttle linkage member can cause the throttle valve to be moved back and forth between the open and closed positions.