A collector for distributing a heat transfer fluid in a heating and/or cooling and/or conditioning network, in particular of household and/or industrial type, includes a housing having: a first terminal portion, open for the entry of the fluid into the collector; a second terminal portion, open for the exit of the fluid from the collector; a duct, which extends from the first terminal portion to the second terminal portion for the passage of the fluid in the housing of the collector, wherein the collector has a shut-off valve positioned at least partly in the duct and including a movable obstructor for adjusting the opening and/or closing of a passage in the duct. The collector further includes: a chamber that communicates with the duct through the passage, in particular when the shut-off valve is in a condition in which it opens the passage, and a plurality of ports that communicate with the chamber, in particular each port being adapted to be associated with a respective branching pipe.

A manifold has a frame and a plurality of valves supported by the frame, each valve having a cross gear that includes four semicircular recesses and four arms that terminate in pointed tips, and wherein the tips are non-jamming rubber tips. The manifold also has a screw drive and a splined rotatable shaft parallel to the screw drive. The manifold further includes a slider driven by the screw drive over the splined rotatable shaft. The slider includes an actuator that protrudes from the slider to engage one of the cross gears to actuate a respective one of the plurality of valves.

Automated systems, methods, techniques, processes, products and product components are provided to implement an advanced and energy efficient hot water heating system control scheme that incorporates an advanced hot water reset for the boilers, including condensing boilers in hydronic systems. The advanced controls are provided to substantially enhance combustion (heating) efficiency for the boilers. The disclosed schemes replace conventional linear hot water reset with a device which can stand alone or integrate with boiler control technology or an existing building automation system to create a unique (non-linear) boiler reset curve based on various inputs. The schemes allow boiler control systems to learn and adapt over time maximizing the efficiency of a condensing boiler plant, by providing an independent, intelligent, economical, monitorable and manipulable solution eliminating the need of a head end BAS control system.

A heating system includes: a heat source machine which heats a heat medium; heating terminals which performs heating using heat of the heat medium; circulation components of the heat medium; a circulation circuit which is configured by connecting the heat source machine, the heating terminals, and the circulation components; and a bypass passage which is arranged in the circulation circuit to bypass the heat source machine. The heat medium heated by the heat source machine and the heat medium of the bypass passage are mixed and circulated. The circulation circuit includes distribution and mixing parts which have a first distribution part for distributing the heat medium heated by the heat source machine, a second distribution part for distributing the heat medium flowing through the bypass passage, and mixing parts for mixing the heat mediums distributed by the first and second distribution parts and corresponding to each other.

A mixing device includes a first inlet (84) and a second inlet (86) inlet and an outlet (80). The first inlet (84) is connected to the outlet (80) via a first flow connection and the second inlet (86) is connected to the outlet (80) via a second flow connection. A circulation pump assembly (24; 46) includes an electric drive motor (30), a control device (34), for controlling the speed of the drive motor (30), and at least one impeller (68; 100) driven by the drive motor. The at least one impeller (68; 100) is positioned in the first flow connection. The flow connections are configured such that at least one hydraulic pressure generated by the impeller (68; 100) in the first flow connection acts as hydraulic resistance in the second flow connection.

A baseboard heating system mounted proximate a juncture of a wall and a floor of a room. The system includes a length of longitudinal piping for the passage of a heated liquid there through and radiating heat fins surrounding the length of longitudinal piping. A heat reflective metal backplate is mounted to the wall behind the length of longitudinal piping and the radiating heat fins. A baseboard heater cover is adapted to cover the piping and heat fins either as an original heater cover or a replacement. The heater cover is supported by the floor and extends at least the length of the longitudinal piping and the radiating heat fins. The heater cover is removably, adjustably and magnetically coupled to the heat reflective metal backplate. The heater cover may be selectively removed to access the longitudinal piping and radiating heat fins and be easily adjusted for proper placement.

The present invention relates to a slidable mounting block for insertion into a rail having a partially closed profile, the mounting block having a front face and a rear face opposite to the front face, the front face facing an open part of the partially closed profile when inserted into the rail. The mounting block comprises a first hole accessible from the front face in a first fixing area of the mounting block and configured for screwing in a threaded part of a first fastener, a recess accessible from the rear face in a second fixing area of the mounting block and configured for holding a head of a second fastener, and a second hole accessible from the front face in the second fixing area, the second hole being co-aligned with the recess and configured for passing a shaft of the second fastener through the mounting block.

Refilling device (11) for a hydronic heating system, having a monolithic housing (21) providing an inlet port (22), an outlet port (23), a middle section (24) providing a flow channel for water extending between the inlet port (22) and the outlet port (23) and a connection socket (25) for a softening and/or demineralization cartridge (26), having an inlet shut-off-valve (27) accommodated within said monolithic housing (21) downstream of said inlet port (22), having an automatically actuated outlet shut-off-valve (28) accommodated within said monolithic housing (21) upstream of said outlet port (23), having a system separator (29) with backflow preventers (30, 31) accommodated within said monolithic housing (21), having a conductivity or TDS sensor (32, 33) accommodated within said monolithic housing (21), having a flow meter (35) accommodated within said monolithic housing (21), and having a controller (37) mounted to said monolithic housing (21), wherein the controller (37) receives signals from the conductivity or TDS sensor (32, 33) and from the flow meter (35), wherein the controller (37) processes said signals received from said sensors to automatically control the operation of the refilling device (11).

Refilling device for a hydronic heating system, having a monolithic housing providing an inlet port, an outlet port, a middle section providing a flow channel for water extending between the inlet port and the outlet port and a connection socket for a softening and/or demineralization cartridge, having an inlet shut-off-valve accommodated within said monolithic housing downstream of said inlet port, having an automatically actuated outlet shut-off-valve accommodated within said monolithic housing upstream of said outlet port, having a system separator with backflow preventers, a conductivity or TDS sensor and a flow meter accommodated within said monolithic housing, and having a controller mounted to said monolithic housing, wherein the controller receives signals from the conductivity or TDS sensor and from the flow meter, wherein the controller processes said signals received from said sensors to automatically control the operation of the refilling device.

A hydraulic manifold for a hydraulic heating and/or cooling system includes a feed conduit (212) and a return conduit (216). The feed conduit (212) includes at least one feed connection (258), and the return conduit (216) includes at least one return connection (260), for the connection of a load circuit (228). A load module (204), in which a section of the feed conduit (212) with the feed connection (258), and a section of the return conduit (216) with the return section (260) are formed, includes at least one mixing device with a pump (232) and with a regulating valve (230), to admix fluid from the return connection (260) to a fluid flow from the feed conduit (212) to the feed connection (258). The section of the feed conduit (212) and the return conduit (216) in each case include an additional contact for connection with a further load module.