A side view fluid meter counter assembly comprises a mounting bracket to mount a mechanical counter to an end of a fluid meter (e.g. gas meter) and a drive mechanism to drive a counter shaft of the mechanical counter from rotational movement of a rotationally driven member of the fluid meter. The rotationally driven member has a drive shaft extending in an end facing direction to connect to the drive mechanism and the mounting bracket mounts the mechanical counter in an orthogonal direction to the end facing direction such that a face of the mechanical counter is viewable from a side of the meter. The drive mechanism may comprise a worm drive. The drive mechanism may further comprise a pair of bevel gears. The mounting bracket further mounts the drive mechanism. Further provided is a fluid meter having a side view counter.

A flow meter, includes a casing, having a central cavity flow communication with an inlet and an outlet conduit; first and second toothed intermeshing oval gears, respectively rotatably supported in the central cavity via a primary support shaft and a secondary support shaft. The first oval gear has an upper surface provided with a protrusion and a magnet, with at least a portion of the magnet arranged within said protrusion, said magnet centered with respect to an axis of rotation of the first gear, and rotating concentrically with respect to the axis of rotation of the first gear; The flowmeter further includes a top cap having an interior cavity; in which a sensor is arranged, so that when the cap is placed on the casing of the flowmeter, the sensor or encoder is situated above the magnet of the first gear. The cap has a bottom surface with a zone of reduced thickness defining a lower recess arranged below the inner cavity of the cap, so that the projection of the first gear is received in the lower recess, so as to aligning and bring the magnet in close proximity with the sensor or encoder thereby avoiding pressure flexing.

A flow meter, includes a casing, having a central cavity flow communication with an inlet and an outlet conduit; first and second toothed intermeshing oval gears, respectively rotatably supported in the central cavity via a primary support shaft and a secondary support shaft. The first oval gear has an upper surface provided with a protrusion and a magnet, with at least a portion of the magnet arranged within said protrusion, said magnet centered with respect to an axis of rotation of the first gear, and rotating concentrically with respect to the axis of rotation of the first gear; The flowmeter further includes a top cap having an interior cavity; in which a sensor is arranged, so that when the cap is placed on the casing of the flowmeter, the sensor or encoder is situated above the magnet of the first gear. The cap has a bottom surface with a zone of reduced thickness defining a lower recess arranged below the inner cavity of the cap, so that the projection of the first gear is received in the lower recess, so as to aligning and bring the magnet in close proximity with the sensor or encoder thereby avoiding pressure flexing.

A flow meter, includes a casing, having a central cavity flow communication with an inlet and an outlet conduit; first and second toothed intermeshing oval gears, respectively rotatably supported in the central cavity via a primary support shaft and a secondary support shaft. The first oval gear has an upper surface provided with a protrusion and a magnet, with at least a portion of the magnet arranged within said protrusion, said magnet centered with respect to an axis of rotation of the first gear, and rotating concentrically with respect to the axis of rotation of the first gear; The flowmeter further includes a top cap having an interior cavity; in which a sensor is arranged, so that when the cap is placed on the casing of the flowmeter, the sensor or encoder is situated above the magnet of the first gear. The cap has a bottom surface with a zone of reduced thickness defining a lower recess arranged below the inner cavity of the cap, so that the projection of the first gear is received in the lower recess, so as to aligning and bring the magnet in close proximity with the sensor or encoder thereby avoiding pressure flexing.

A flow meter, includes a casing, having a central cavity flow communication with an inlet and an outlet conduit; first and second toothed intermeshing oval gears, respectively rotatably supported in the central cavity via a primary support shaft and a secondary support shaft. The first oval gear has an upper surface provided with a protrusion and a magnet, with at least a portion of the magnet arranged within said protrusion, said magnet centered with respect to an axis of rotation of the first gear, and rotating concentrically with respect to the axis of rotation of the first gear; The flowmeter further includes a top cap having an interior cavity; in which a sensor is arranged, so that when the cap is placed on the casing of the flowmeter, the sensor or encoder is situated above the magnet of the first gear. The cap has a bottom surface with a zone of reduced thickness defining a lower recess arranged below the inner cavity of the cap, so that the projection of the first gear is received in the lower recess, so as to aligning and bring the magnet in close proximity with the sensor or encoder thereby avoiding pressure flexing.

A dispensing system for dispensing hot melt adhesive foam onto a substrate is described. The dispensing system comprises a pump having a first input to receive a hot melt adhesive and a second input to receive a gas, where the pump mixes the hot melt adhesive and the gas to produce a solution and pump the solution at a volumetric flow rate. The dispensing system also includes a valve to control an amount of the gas provided to the pump from the second input, a flow meter to measure the volumetric flow rate of the solution pumped by the pump, and a dispenser to receive the solution from the pump and dispense the solution to create the hot melt adhesive foam.

A dispensing system for dispensing a hot melt adhesive foam onto a substrate is described. The dispensing system comprises a pump having a first input to receive a hot melt adhesive and a second input to receive a gas, where the pump mixes the hot melt adhesive and the gas to produce a solution. The dispensing system also includes a temperature sensor to detect a temperature of the solution, a dispenser to receive the solution from the pump and dispense the solution, and a controller. The controller instructs the pump to operate at a first speed, receives the temperature of the solution, and instructs the pump to operate at a second speed that is different than the first speed in response to the signal.

A fluid management system includes a fluid management controller and a fluid dispenser. The controller authorizes control of the one or more fluid management components over a wireless interface. A dispensing meter can be activated by an authentication device. The fluid meter includes a cartridge valve with a valve cartridge and a valve stem. The cartridge valve guides the valve stem and provides the only sealing surface for the dynamic seals and control seal disposed on the valve stem. The handheld meter dispenses through a nozzle, which includes an overmolded stem tip that generates a laminar fluid flow as the fluid exits the nozzle. The handheld fluid meter includes circuitry configured to invert the orientation of a visual output provided by a display of the handheld fluid meter to facilitate installation of the handheld fluid meter for use in an oil bar application.

In one embodiment, the present disclosure includes a solid dispenser including dispensing vanes coupled rotationally about respective parallel horizontal axes. The two dispensing vanes including a surface at a radial distance from the corresponding parallel horizontal axis with teeth arranged on and projecting from the surface. The surfaces of the dispensing vanes may be in contact between the parallel horizontal axes and are flexible in radial directions of the dispensing vanes. In one example embodiment, the dispensing vanes are configured to rotate in opposing directions about the respective parallel horizontal axes to selectively dispense ingredients from a hopper.

A gas meter with a rated maximum flow capacity of greater than 3,000 CFH (Cubic Feet per Hour)—for example, between 3,500 CFH and 7,000 CFH—is provided with 2-inch flange connectors. One or more undercuts are provided in the meter body to promote satisfactory performance in terms of, for example, differential pressures at the meter inlet and outlet.