A fluid level monitor incorporated into a fuel tank. A sensor module is adapted to being mounted to an exterior of the tank. A tube extends from the module within the tank and secures a housing at an interior location. The housing has a gear assembly, a float arm pivotally secures to the gear assembly and, in response to changes in a fluid level of the tank, causes the gear assembly to rotate a drive rod extending within the tube. A coupler forms a portion of the sensor module and is secured to an upper end of the drive rod. Rotation of the coupler relative to a PCB integrated into the sensor module produces an inductive signal indicative of the amount of displacement of the float and, consequently, the level of the fluid within the tank.

A fluid level monitor incorporated into a fuel tank. A sensor module is adapted to being mounted to an exterior of the tank. A tube extends from the module within the tank and secures a housing at an interior location. The housing has a gear assembly, a float arm pivotally secures to the gear assembly and, in response to changes in a fluid level of the tank, causes the gear assembly to rotate a drive rod extending within the tube. A coupler forms a portion of the sensor module and is secured to an upper end of the drive rod. Rotation of the coupler relative to a PCB integrated into the sensor module produces an inductive signal indicative of the amount of displacement of the float and, consequently, the level of the fluid within the tank.

An indicator assembly for determining a liquid level condition within a tank includes a dial assembly with a base and a lens or cover connected to the base. A channel is formed in the lens and a go-no-go protrusion projects into the channel. An actuator is located between the base and the cover and is movable in response to a change in liquid level in the tank. The indicator assembly also includes a sensor module for insertion into the channel. The sensor module has a housing with a sensor for determining movement of the actuator in response to a change in liquid level. A go-no-go cavity complementary in shape with the go-no-go protrusion is formed in the housing so that the sensor module can be fully inserted into the housing with the sensor aligned with the actuator for generating signals related to the liquid level condition.

An indicator assembly for determining a liquid level condition within a tank includes a dial assembly with a base and a lens or cover connected to the base. A channel is formed in the lens and a go-no-go protrusion projects into the channel. An actuator is located between the base and the cover and is movable in response to a change in liquid level in the tank. The indicator assembly also includes a sensor module for insertion into the channel. The sensor module has a housing with a sensor for determining movement of the actuator in response to a change in liquid level. A go-no-go cavity complementary in shape with the go-no-go protrusion is formed in the housing so that the sensor module can be fully inserted into the housing with the sensor aligned with the actuator for generating signals related to the liquid level condition.

A fluid level sensor for sensing a level of a fluid within a toroid-shaped tank includes a float ring, a float structure, a gauge shaft, and a tiller arm. The float ring rotate s within the toroid-shaped tank about a first rotational axis. The float structure exhibits buoyancy in the fluid disposed within the toroid-shaped tank and supplies a force to the float ring based on the level of the fluid within the toroid-shaped tank. The gauge shaft is mounted for rotation about a second rotational axis and rotates about the second rotational axis to a position representative of the level of the fluid within the toroid-shaped tank. The tiller arm supplies the rotational drive force to the gauge shaft when the float ring rotates.

A fluid level sensor for sensing a level of a fluid within a toroid-shaped tank includes a float ring, a float structure, a gauge shaft, and a tiller arm. The float ring rotate s within the toroid-shaped tank about a first rotational axis. The float structure exhibits buoyancy in the fluid disposed within the toroid-shaped tank and supplies a force to the float ring based on the level of the fluid within the toroid-shaped tank. The gauge shaft is mounted for rotation about a second rotational axis and rotates about the second rotational axis to a position representative of the level of the fluid within the toroid-shaped tank. The tiller arm supplies the rotational drive force to the gauge shaft when the float ring rotates.

A CIR-modified milling machine includes a milling drum that is adapted to mill material from a roadway, which milling drum is contained in a milling drum housing. An additive spray assembly is located within the milling drum housing and adapted to dispense an asphalt additive therein. An additive flow system includes an inlet line that is adapted to be operatively connected to an external supply line, a surge tank for asphalt additive that is in fluid communication with the additive spray assembly, and an additive pump for pumping asphalt additive from the surge tank to the additive spray assembly.

A liquid level gauge for determining the level or volume of liquid within a tank includes a mounting head adapted for connection to the tank, a gauge assembly connected to one side of the mounting head, and an elongate sensing probe assembly extending into the tank. The gauge assembly includes a rotatable gauge plate with a scale located thereon and a rotatable indicator that moves across the scale in response to a change in liquid level. The gauge plate is weighted for rotation toward a gravitational force vector for orientation with an upper surface of the liquid in the tank independent of tank tilt. The sensing probe includes a float rod with an integral coil spring hinge to facilitate installation of the gauge within the tank. A counterweight is adjustable along the float rod to fine-tune float weight or buoyancy for a particular gauge configuration and liquid type.

A liquid level gauge for determining the level or volume of liquid within a tank includes a mounting head adapted for connection to the tank, a gauge assembly connected to one side of the mounting head, and an elongate sensing probe assembly extending into the tank. The gauge assembly includes a rotatable gauge plate with a scale located thereon and a rotatable indicator that moves across the scale in response to a change in liquid level. The gauge plate is weighted for rotation toward a gravitational force vector for orientation with an upper surface of the liquid in the tank independent of tank tilt. The sensing probe includes a float rod with an integral coil spring hinge to facilitate installation of the gauge within the tank. A counterweight is adjustable along the float rod to fine-tune float weight or buoyancy for a particular gauge configuration and liquid type.

A CIR-modified milling machine includes a milling drum that is adapted to mill material from a roadway, which milling drum is contained in a milling drum housing. An additive spray assembly is located within the milling drum housing and adapted to dispense an asphalt additive therein. An additive flow system includes an inlet line that is adapted to be operatively connected to an external supply line, a surge tank for asphalt additive that is in fluid communication with the additive spray assembly, and an additive pump for pumping asphalt additive from the surge tank to the additive spray assembly.