The invention relates to a method for cooling a tool in a heat treatment furnace, wherein: the tool is supplied during normal cooling operation with coolant from a coolant reservoir through a supply inlet (1), which coolant is returned into the coolant reservoir from the tool via a return flow (2); the supply inlet (1) is coupled by means of an electric actuator (3) alternatively to the coolant reservoir or to the public water supply and the return flow (2) is coupled by means of a further electric actuator (3) alternatively to the coolant reservoir or to the public waste water system (4); the actuators (3, 3) are supplied with a feed current during normal cooling operation and held in a first position in which coolant is supplied to the tool through the supply inlet (5) from the coolant reservoir and the coolant is fed back through the return flow (2, 6) into the coolant reservoir; and, upon interruption in the power supply, the actuators (3, 3) are forced into an emergency position in which cold water is supplied to the tool through the supply inlet (7) from the public water supply and the water is discharged through the return flow (2, 8) into the public waste water system (4).

A flow tube including: a pin; a seat; and a guide tube, the pin and the seat are arranged at least partially in the guide tube; and wherein: the flow tube is arranged to have a closed position, wherein: the pin is in contact with the seat and fluid flow through the seat is reduced or prevented; the flow tube is arranged to have an open position, wherein: the pin is not in contact with the seat and fluid flow is increased through the seat when compared to the closed position; and the flow tube is arranged to have a forced open position, wherein: the seat is arranged such that when a force above a threshold force is applied to the seat: the seat moves away from the pin, the pin is not in contact with the seat, and the flow tube cannot move to the closed position again.

An apparatus and method controls an environmental control system to maintain a differential pressure between a room and one or more adjacent areas by (1) determining a differential pressure error based on the differential pressure and a differential pressure set point using a proportional-integral-derivative (PID) controller; (2) increasing an air change per hour set point whenever one or more first parameters are satisfied; (3) decreasing the air change per hour set point whenever one or more second parameters are satisfied; and (4) sending one or more control signals to the environmental control system that maintain the differential pressure between the room and the one or more adjacent areas by adjusting: (a) the leading airflow to be approximately equal to the air flow change set point multiplied by a volume of the room divided by 60, and (b) the tracking airflow to maintain a volume differential set point.

A transmission device comprises an input shaft, a screw shaft extending in a direction orthogonal to the input shaft, a transmission member which forms an annular shape surrounding the screw shaft and rotates around the screw shaft by a power which is input from the input shaft, and a nut which is mounted to the screw shaft and rotates by the power transmitted from the transmission member. The nut is disposed on an axis orthogonal to the screw shaft and the input shaft.

The disclosure generally relates to compositions, methods, and systems for heat transfer and methods of preparing heat transfer mediums. In various embodiments are described heat transfer mediums comprising a plurality of microparticles suspended in a bulk material with each microparticle containing a phase change material. In other embodiments are described fluids comprising of a slurry of microparticles containing phase change fluid in a carrier liquid for a fast charger system.

An inlet pressure valve regulation system to provide a regulated fluid flow includes a housing, first piston assembly, regulating valve, and inlet pressure conduit. The housing has an inlet at an inlet end which receives a pressurized fluid and an outlet at an outlet end which provides the regulated fluid flow. The piston assembly is arranged in the housing and has a first cavity and a control orifice to fluidly connect the inlet to the first cavity. The first piston assembly is configured to regulate the fluid flow. The regulating valve has a first valve chamber, a second valve chamber fluidly connected to a vent, a floating valve seat disposed between the first valve chamber and the second valve chamber, and a valve component. The floating valve seat includes a diaphragm and a seat having a passageway to fluidly connect the first valve chamber and the second valve chamber.

Hydraulic systems and associated methods configured to reduce leakage past a spool valve when the system is in a neutral state. Leakage reduction is achieved by shifting the spool valve within the spool bore. The amount of shifting can be controlled by a pressure controller that sets one or pressures in the system and actively/dynamically adjusts the system to achieve a desired pressure or set of pressures by shifting the spool valve.

Differential pressure sensors, control, and associated methods are disclosed. An example apparatus includes a first housing including a first port, the first port fluidly coupled to a first location, first fluid to flow into the first port from the first location, a second housing coupled to the first housing, the second housing including a second port, the second port fluidly coupled to a second location, second fluid to flow into the second port from the second location, and a piston slidably disposed between the first and second housings, the first and second fluids to cause movement of the piston, the movement of the piston corresponding to a differential pressure between the first and second locations.

A valve system having a valve with a moveable armature and a pneumatic actuation apparatus, a controller, a computer program product for simulating operating behavior of the valve system and an operating method for the valve system, wherein the valve is provided in an active operating state and a valve position to be approached is specified, a target differential pressure corresponding to the valve position to be approached that is to be set in the pneumatic actuation apparatus is determined, a differential pressure in the pneumatic actuation apparatus is changed and the differential pressure present is detected, and the differential pressure present is stabilized if a deviation between the differential pressure present and the target differential pressure falls below a settable threshold value in terms of amount.

A pressure regulator assembly has a normal mode and a regulated fast-fill mode and includes a spring cage and a body coupled together. The spring cage and body define an inlet in fluid communication with an outlet as well as an interior between the inlet and the outlet. A diaphragm assembly mounts in the interior for selectively closing a flowpath between the inlet and the outlet. A preload spring in the interior applies force on the diaphragm assembly so that in the normal mode, the flowpath is closed if a downstream pressure is above a first pressure. An actuation assembly includes a lever coupled to the spring cage and a push rod mounted so that in the regulated fast-fill mode, the lever slides so that the push rod further compresses the preload spring to open the flowpath and regulate flow therethrough if the downstream pressure is below a second pressure.