A mechano-caloric stage includes an elongated outer sleeve. An elongated inner sleeve is disposed within the elongated outer sleeve. A pair of pistons is received within the elongated inner sleeve. Each of the pair of pistons is positioned at a respective end of the elongated inner sleeve. The pair of pistons are moveable relative to the elongated inner sleeve. A mechano-caloric material is disposed within the elongated inner sleeve between the pair of pistons. The mechano-caloric material is compressible between the pair of pistons.

A supplemental heating system includes an enclosure that encloses a primary heating device. The enclosure includes an inlet damper, an outlet damper, and an intermediate damper. In an idle state, the inlet damper and outlet damper are open while the intermediate damper is closed. In an active state, the inlet damper and outlet damper are closed while the intermediate damper is open, so that air is circulated within the enclosure.

A supplemental heating system includes an enclosure that encloses a primary heating device. The enclosure includes an inlet damper, an outlet damper, and an intermediate damper. In an idle state, the inlet damper and outlet damper are open while the intermediate damper is closed. In an active state, the inlet damper and outlet damper are closed while the intermediate damper is open, so that air is circulated within the enclosure.

The present invention relates to the technical field of bee product processing, and discloses a continuous drying apparatus for bee pollen and related drying method. The continuous drying apparatus for bee pollen comprises: a box body; a first drying conveying structure; a second drying conveying structure; and a heat pump dehumidification heating structure. The continuous drying apparatus for bee pollen has the advantage of high drying efficiency.

The present invention relates to the technical field of bee product processing, and discloses a continuous drying apparatus for bee pollen and related drying method. The continuous drying apparatus for bee pollen comprises: a box body; a first drying conveying structure; a second drying conveying structure; and a heat pump dehumidification heating structure. The continuous drying apparatus for bee pollen has the advantage of high drying efficiency.

A direct heat exchange system uniformly transfers heat through a multiphase substance, such as a refrigerant, to a barrier that emits heat radiantly and convectively. The system solely uses the multiphase substance to exchange heat between the multiphase substance and the barrier. No intermediary fluids are used. A heat exchange portion, such as a heat pump, absorbs and emits heat and transfers it to the multiphase substance. A tube portion carries the multiphase substance to the barrier. The heat is directly exchanged between the tube and the barrier. The barrier emits radiant heat or absorbs heat. A tube fastener fastens the tube to the barrier. A thermal mass portion stores heat behind the barrier. A dehumidification coil helps prevent indoor condensation and tempers the temperature of the air proximal to the barrier by drying the air. A decorative panel covers the tube portion and the thermal mass portion.

A direct heat exchange system uniformly transfers heat through a multiphase substance, such as a refrigerant, to a barrier that emits heat radiantly and convectively. The system solely uses the multiphase substance to exchange heat between the multiphase substance and the barrier. No intermediary fluids are used. A heat exchange portion, such as a heat pump, absorbs and emits heat and transfers it to the multiphase substance. A tube portion carries the multiphase substance to the barrier. The heat is directly exchanged between the tube and the barrier. The barrier emits radiant heat or absorbs heat. A tube fastener fastens the tube to the barrier. A thermal mass portion stores heat behind the barrier. A dehumidification coil helps prevent indoor condensation and tempers the temperature of the air proximal to the barrier by drying the air. A decorative panel covers the tube portion and the thermal mass portion.

A controller for controlling an environmental condition of a building via building equipment includes a user interface configured to present information to a user, an air quality sensor configured to sense indoor air quality conditions, a communications interface configured to communicate with a server system and receive outdoor air quality data from the server system, and a processing circuit. The processing circuit is configured to generate indoor air quality data based on the sensed indoor air quality data conditions sensed by the air quality sensor, receive, via the communications interface, the outdoor air quality data from the server system, and generate one or more interfaces indicating the indoor air quality conditions and the outdoor air quality conditions based on the indoor air quality data and the outdoor air quality data and cause the user interface to display the one or more interfaces.

A controller for controlling an environmental condition of a building via building equipment includes a user interface configured to present information to a user, an air quality sensor configured to sense indoor air quality conditions, a communications interface configured to communicate with a server system and receive outdoor air quality data from the server system, and a processing circuit. The processing circuit is configured to generate indoor air quality data based on the sensed indoor air quality data conditions sensed by the air quality sensor, receive, via the communications interface, the outdoor air quality data from the server system, and generate one or more interfaces indicating the indoor air quality conditions and the outdoor air quality conditions based on the indoor air quality data and the outdoor air quality data and cause the user interface to display the one or more interfaces.

The present disclosure relates to issues that may arise from power loss in temperature control systems, such as a heat pump or thermal engine. According to the present disclosure, a temperature control system may comprise a temperature-controlling device configured to control a temperature-controlled unit. The temperature-controlling device and the temperature-controlling device may be thermally connectable through a thermal path connector. The thermal path connector may be actuatable, wherein actuation of the thermal path connector breaks the thermal path between the temperature-controlling device and the temperature-controlled unit, wherein the break limits temperature leak. Actuation may occur during power loss, which may allow for sustained temperatures without additional power.