The present disclosure provides methods and systems for mitigating finished product temperature transients caused by changes in product flow, raw product temperature, or other disturbances in an aseptic sterilization process. The methods and systems include applying an energy balance feedforward control scheme to the aseptic sterilization process to compensate for raw product temperature changes and changes in product flow. The methods and systems prevent damage to a finished product from occurring based on adverse transient temperature responses of heaters and coolers in an aseptic sterilization process.

An air-conditioning setting screen has a coordinate space defined by a Y-axis along which temperature items are indicated in increments of one degree and an X-axis along which time-point items are indicated in increments of one hour. Operation points PT corresponding to the time-point items are arranged in the coordinate space. The air-conditioning setting screen displays time-series changes in a previous day's body-movement values such that the density of a background color is higher for times at which the body-movement value is larger and the density of a background color is lower for times at which the body-movement value is smaller.

This cartridge comprises a base (10), a fixed attached piece (20), a spool (30) for controlling the temperature of the mixture of the hot and cold fluids, and a thermostatic element making it possible to move the spool along an axis. The base simultaneously delimits an outlet orifice (16) for the mixture, an inlet orifice (14) for the cold fluid that supplies, via a first distribution channel (F4), cold fluid around the spool, a passage (F3), delimited axially between the spool and the base, and an inlet orifice (15) for the hot fluid that supplies, via a second channel (C4) for distribution hot fluid around the spool, a passage (C3) delimited axially between the spool and the attached piece. In order for the base to remain simple and cost-effective to produce, while still favoring the flow of high fluid flow rates through it, the invention proposes to close, axially toward the outlet orifice, the first distribution channel by means of the spool and the second distribution channel by means of the attached piece.

A water delivery device includes a body, a user interface, a micro-mixing valve, first and second capacitive sensors, and a controller. The body includes a base and a spout. The user interface is provided on the spout. The micro-mixing valve is contained within the body and is in fluid communication with a hot water source and a cold water source. The first capacitive sensor is provided below the user interface. The second capacitive sensor is provided below the user interface and is spaced apart from the first capacitive sensor. The controller is operatively connected to the first capacitive sensor, the second capacitive sensor, and the micro-mixing valve. Each of the first and second capacitive sensors is configured to be independently activated by a user to transmit a signal to the controller to increase or decrease a temperature of a flow of water flowing from the micro-mixing valve.

A mixer water faucet for installation through a bore in a work surface in proximity to a water supply, includes a stationary housing extending transversely through the bore; a faucet body mounted onto the housing, rotatable relative thereto; a main spout and an auxiliary spout extending from the housing; a main water supply hose for conveying water to the main spout and an auxiliary water supply hose for conveying water to the auxiliary spout, the main water supply hose and the auxiliary water supply hose extending through the housing; and a diverter for selectably directing a supply of water to the main spout and the auxiliary spout.

The present invention limits fluid temperature at a point in a fluidic system to below a predetermined temperature by cooling the fluid when needed and without requiring a separate cold fluid source. The present invention “clips” the temperature of the fluid at a point in the system to within a temperature range and prevents overcooling the fluid. When the fluid temperature is below the temperature range, the temperature of the fluid is unchanged as it passes through the apparatus of the present invention. The present invention may operate without external power, can function in any orientation, and works for unpressurized and pressurized systems. The present invention has application in the areas of solar thermal energy systems, fluid tanks, engine oil and coolant systems, transmission fluid systems, hydraulic systems, machining fluid systems, cutting fluid systems, nuclear reactors and chemical reactors, among others.

Thermostatic cartridge for a mixing valve for mixing a cold incoming fluid and a hot incoming fluid in a determined proportion to form a mixture. A head includes a housing extending along a central axis, and a thermostatic regulating assembly. A regulating system defines an abutment surface adjustable in axial translation with respect to the head. A thermostatic system includes a heat sensitive first portion over which the mixture can flow, and a second portion to abut axially against the abutment surface. The first portion can move the second portion axially between plural positions relative to the first portion, the relative positions determined by the mixing temperature. A slide mounted on the first portion moves axially relative to the head for modifying the determined proportion, and may slide between a normal position and plural overtravel positions axially closer to the head than the normal position.

Temperature adjusting device couplable with a valve body of a thermostatic mixing valve, including: a hollow housing provided with a wall having at least one portion shaped for coupling firmly with an opening end provided on the valve body; an adjusting element received inside the housing and movable along an operating direction with respect to the housing between a first calibrating position and a second calibrating position to adjust, in use, a mixing temperature of a flow of water exiting the valve body; on the wall at least one opening being obtained that is shaped for receiving a locking element, the adjusting element including an abutting portion shaped for abutting on the locking element so as to arrest a movement of the adjusting element and limit a stroke thereof between the first and second calibrating position.

A pressure balance valve of an internal retention structure includes a control head, a valve housing, a balance valve assembly, and a valve seat assembly. The balance valve assembly includes a balance valve body, a piston, and sealing elements. The valve seat assembly includes a valve seat, two water stop sleeves, and a plug cap. The valve seat is integrally formed with a valve core chamber receiving therein balance valve assembly and closed by the plug cap. The valve seat assembly forms sealed and movable engagement with the control head by means of the water stop sleeves. Positioning between the valve core the valve seat and the valve housing can be made more accurate and more reliable and sealing performance of the valve core is improved.

A pressure balance valve of an internal retention structure includes a control head, a valve housing, a balance valve assembly, and a valve seat assembly. The balance valve assembly includes a balance valve body, a piston, and sealing elements. The valve seat assembly includes a valve seat, two water stop sleeves, and a plug cap. The valve seat is integrally formed with a valve core chamber receiving therein balance valve assembly and closed by the plug cap. The valve seat assembly forms sealed and movable engagement with the control head by means of the water stop sleeves. Positioning between the valve core the valve seat and the valve housing can be made more accurate and more reliable and sealing performance of the valve core is improved.