A water outlet structure capable of being disassembled for cleaning comprises an inner core and a core holder. The core holder is hollow. The inner core is inlaid in the core holder to form a jet flow core body. A plurality of water outlet channels are formed between the core holder and the inner core matched with the core holder and are arrayed in the circumferential direction to form circular tracks. An inclined guide side wall and an inclined guide outer wall are formed in each water outlet channel, so an interwoven net-like water pattern or a locally-narrowed water pattern is sprayed out by the water outlet channels. The water outlet channels are formed in the inner core and the core holder so that the water outlet structure can be conveniently disassembled for cleaning when impurities are accumulated in the channels.

A water outlet structure capable of being disassembled for cleaning comprises an inner core and a core holder. The core holder is hollow. The inner core is inlaid in the core holder to form a jet flow core body. A plurality of water outlet channels are formed between the core holder and the inner core matched with the core holder and are arrayed in the circumferential direction to form circular tracks. An inclined guide side wall and an inclined guide outer wall are formed in each water outlet channel, so an interwoven net-like water pattern or a locally-narrowed water pattern is sprayed out by the water outlet channels. The water outlet channels are formed in the inner core and the core holder so that the water outlet structure can be conveniently disassembled for cleaning when impurities are accumulated in the channels.

A reaction apparatus comprising at least one tubular reaction unit (23), a container (41) configured to accommodate the tubular reaction unit (23) and a temperature control medium (51) used in heat exchange with the tubular reaction unit (23), and a nozzle (31) configured to eject the temperature control medium (51) toward the tubular reaction unit (23) in the container. The reaction apparatus further comprising a movable part (34) configured to adjust an ejection direction of the nozzle (31) is preferred. The reaction apparatus allows for effectively performing the temperature control even when the tubular reaction unit is immersed in a temperature control medium.

A reaction apparatus comprising at least one tubular reaction unit (23), a container (41) configured to accommodate the tubular reaction unit (23) and a temperature control medium (51) used in heat exchange with the tubular reaction unit (23), and a nozzle (31) configured to eject the temperature control medium (51) toward the tubular reaction unit (23) in the container. The reaction apparatus further comprising a movable part (34) configured to adjust an ejection direction of the nozzle (31) is preferred. The reaction apparatus allows for effectively performing the temperature control even when the tubular reaction unit is immersed in a temperature control medium.

A concealed flow regulator includes a water supply opening providing a water flow and disposed with threads; a housing portion connected to the water supply opening and forming an air flow clearance therewith that communicates with exterior air, having an external revolution surface disposed with external threads and in which is defined a mutation cavity and a suction passage in communication with the mutation chamber and having an external port disposed in the external revolution surface in communication with the air flow clearance and an internal port that connects an interior portion of the mutation cavity with the exterior air; and a diversion device assembled within the housing portion through which the water flow flows into the mutation chamber and generates a negative pressure which sucks in exterior air via the air flow clearance and the suction passage that mixes with the divided water flow to produce bubble water.

A concealed flow regulator includes a water supply opening providing a water flow and disposed with threads; a housing portion connected to the water supply opening and forming an air flow clearance therewith that communicates with exterior air, having an external revolution surface disposed with external threads and in which is defined a mutation cavity and a suction passage in communication with the mutation chamber and having an external port disposed in the external revolution surface in communication with the air flow clearance and an internal port that connects an interior portion of the mutation cavity with the exterior air; and a diversion device assembled within the housing portion through which the water flow flows into the mutation chamber and generates a negative pressure which sucks in exterior air via the air flow clearance and the suction passage that mixes with the divided water flow to produce bubble water.

An end effector for interfacing with a nozzle is disclosed. The end effector comprises a first end, which includes a receptacle. The end effector comprises one or more retention features positioned along a perimeter of the receptacle, where each of the one or more retention features is movable between a first position and a second position. Each of the one or more retention features is configured to lock the nozzle by securing onto a corresponding one of the one or more nozzle retention features in the first position, and to release the nozzle in the second position. The end effector may further comprise one or more actuators and a first channel, which includes a first inlet and a first outlet. A method of using an end effector to interface with a nozzle is also disclosed.

An end effector for interfacing with a nozzle is disclosed. The end effector comprises a first end, which includes a receptacle. The end effector comprises one or more retention features positioned along a perimeter of the receptacle, where each of the one or more retention features is movable between a first position and a second position. Each of the one or more retention features is configured to lock the nozzle by securing onto a corresponding one of the one or more nozzle retention features in the first position, and to release the nozzle in the second position. The end effector may further comprise one or more actuators and a first channel, which includes a first inlet and a first outlet. A method of using an end effector to interface with a nozzle is also disclosed.

The disclosure provides methods and probes used to dispense flowable materials from a packaged source, such as a bag in box container. The probes are adapted to engage with one or more dispensing components, for example, spouts, faucets, caps, bags, boxes, or other dispensing components. The disclosure also provides methods of using the probe, including connecting the probe to one or more dispensing components, for example flip caps, and methods of dispensing the packaged flowable material.

The disclosure provides methods and probes used to dispense flowable materials from a packaged source, such as a bag in box container. The probes are adapted to engage with one or more dispensing components, for example, spouts, faucets, caps, bags, boxes, or other dispensing components. The disclosure also provides methods of using the probe, including connecting the probe to one or more dispensing components, for example flip caps, and methods of dispensing the packaged flowable material.