Disclosed are various embodiments of a lockable toilet fill valve and methods according to the present invention. In one embodiment, a toilet fill valve includes a float/arm assembly. The toilet fill valve is closed when the float/arm assembly is disposed in a first position. The toilet fill valve being open when the float/arm assembly is disposed in a second position. A valve lock is associated with the float/arm assembly. The valve lock includes an unlock position and a lock position, wherein the valve lock fixes the float/arm assembly in the first position when the valve lock is in the lock position.

Disclosed are various embodiments of a lockable toilet fill valve and methods according to the present invention. In one embodiment, a toilet fill valve includes a float/arm assembly. The toilet fill valve is closed when the float/arm assembly is disposed in a first position. The toilet fill valve being open when the float/arm assembly is disposed in a second position. A valve lock is associated with the float/arm assembly. The valve lock includes an unlock position and a lock position, wherein the valve lock fixes the float/arm assembly in the first position when the valve lock is in the lock position.

An apparatus for providing an extracorporeal blood circuit control includes a base module having a control device and a patient module releasably connected to the base module and having blood-conducting components of the extracorporeal blood circuit. A pivot system is also provided at the base module and at the patient module to pivot the patient module relative to the base module about a horizontal axis.

Monitoring systems and methods for a relief valve system. In one example, a monitoring system for a relief valve includes at least one tilt sensor coupled to one or more of a cover or a latch of the relief valve. The at least one tilt sensor is associated with an interface. Upon detection by the at least one tilt sensor that one of the cover is open or the latch is unlocked, a signal is transmitted by the interface indicating one or more of the cover is open or the latch is unlocked.

In various implementations, an electronic actuator may be coupled to a valve to provide the ability to shut off anhydrous ammonia flow through the valve (e.g., in emergencies). The valve may be coupled to anhydrous ammonia tanks, such as nurse tanks and/or storage tanks. The electronic actuator may include a handle and a bracket. The handle and the bracket may include at least two attractive components that are magnetically attracted to each other upon application of an electric current and the valve may be open. When the electric current is cut, the attractive components of the handle and the bracket may not be magnetically attracted to each other and the valve may be shut off. A controller (e.g., a switch) may be coupled to the electronic actuator to allow control of the electric signal to the electronic actuator.

A device for transmitting movement between a first rotating and driving toothed element and a second rotating and driven toothed element, the transmitting of movement being limited to a range of rotation that is delimited by starting and ending rotational angular positions of ranges of movement for the toothed elements. The second toothed element has a spring element pulling it in rotation in a direction opposite to the positive direction of rotation bringing the second toothed element from its beginning angular position of operational range of movement to its ending angular position of operational range of movement, and the first toothed element has a particular peripheral arc portion that is devoid of teeth, this particular peripheral arc portion extending circumferentially beyond the end or the last tooth of the toothed peripheral arc portion of the first element, seen in the positive direction of rotation of the latter.

A device for transmitting movement between a first rotating and driving toothed element and a second rotating and driven toothed element, the transmitting of movement being limited to a range of rotation that is delimited by starting and ending rotational angular positions of ranges of movement for the toothed elements. The second toothed element has a spring element pulling it in rotation in a direction opposite to the positive direction of rotation bringing the second toothed element from its beginning angular position of operational range of movement to its ending angular position of operational range of movement, and the first toothed element has a particular peripheral arc portion that is devoid of teeth, this particular peripheral arc portion extending circumferentially beyond the end or the last tooth of the toothed peripheral arc portion of the first element, seen in the positive direction of rotation of the latter.

A restricted access lockout system restricts access to remotely operated hydraulically actuated valves by utilizing a processor to compare each user's access code against a stored list. The user access code may be provided by card key with an embedded RFID chip, a designated application on a personal device such as a smart phone or smart pad that may communicate with the processor via Bluetooth, Wi-Fi, Internet, or radio. Once the processor grants access to operate various designated hydraulically actuated valves the designated hydraulically actuated valves are unlocked for designated period of time. After the designated period of time expires the hydraulically actuated valves are relocked. Generally, the lock is via a hydraulic cylinder where the hydraulic fluid may be isolated through one or more solenoid control valves. Hydraulic fluid within the hydraulic cylinder and the cylinder provide a sufficient counter to apply force so that the hydraulically actuated valves may not be manipulated. In certain instances, the hydraulic locks may be replaced by mechanical lock. In other instances, the hydraulic cylinders may be supplied with pressurized hydraulic fluid supply by hydraulic pump wherein the pump is actuated by the processor upon command by a user. The pressurized hydraulic fluid and the hydraulic cylinders may in turn allow the user to remotely actuate the hydraulically actuated valves.

An anti-tampering mechanism for a fire hydrant that blocks inflow of fluids and materials through the pamper outlet into the lower barrel of the hydrant and to the water main. This mechanism comprises a modular valve, which stem extends only through the top barrel of the hydrant, and is in mechanical engagement and disengagement with a bottom seat that closes the top opening of the lower barrel. Thus, this mechanism blocks tampering with the water in both closed and open states of the valve. Further, the fire hydrant comprises a monitoring and anti-theft mechanism that comprises fluid flow sensors, wireless communication means and electronics accommodated in a housing that is attached to the lower barrel and and protectively enveloping them against tampering, vandalism and sabotaging.

An anti-tampering mechanism for a fire hydrant that blocks inflow of fluids and materials through the pamper outlet into the lower barrel of the hydrant and to the water main. This mechanism comprises a modular valve, which stem extends only through the top barrel of the hydrant, and is in mechanical engagement and disengagement with a bottom seat that closes the top opening of the lower barrel. Thus, this mechanism blocks tampering with the water in both closed and open states of the valve. Further, the fire hydrant comprises a monitoring and anti-theft mechanism that comprises fluid flow sensors, wireless communication means and electronics accommodated in a housing that is attached to the lower barrel and and protectively enveloping them against tampering, vandalism and sabotaging.