A tool for an approach and mechanism for calculating and configuring memory mapping of trend log objects in a system, such as an HVAC. It may incorporate determining available memory of a controller for trending a unit of equipment of a system. A calculation of available records may be made for configuring and using a trend. The calculation may be made in view of the controller memory and parameters including buffer size, log interval and retention time. A change in parameters may cause a recalculation of available records. The “available record” terms may be regarded as being in a user-understandable format. The format may be intuitive. Anomalies of trends of equipment may lead to spotting issues of the equipment.

Systems and methods for HVAC system design and zone group management are disclosed. A floor plan of a building is received, and an HVAC system configuration is selected from among a set of template HVAC configurations. HVAC components are selected from set of template HVAC components to customize the configuration. As components are selected, candidate positions for the HVAC component within the HVAC system configuration are determined and presented to a user to ensure compliance with engineering requirements. The floor plan includes a mapping of an HVAC system configuration to an HVAC zone group. If a change is made to the HVAC system configuration of a zone associated with a zone group, it is determined if another zone group shares the same properties as the changed HVAC configuration. If one exists, the changes zone is moved to the new zone group. If not, a new zone group is created and the changes zone is moved to the new zone group.

Aspects of the invention are directed towards a system and a method of controlling temperature of different zones inside premises based on determining an effective temperature set point. One or more dynamically sensed parameters are received from a plurality of sensors strategically placed within and outside of a building. One or more static parameters corresponding to building configurations and temperature thresholds from a memory unit are retrieved. A correlation engine determines the effective temperature set point for individual VAV controller associated with a particular pre-defined zone in the building by establishing a correlation between the one or more dynamically sensed parameters and static parameters corresponding to that zone. The effective temperature setpoint is transmitted to a VAV controller for associated zone.

In a continuous kneading apparatus according to an embodiment, for each of a plurality of ring-shaped heaters, a control unit determines a current state and a reward for an action selected in the past based on a control error calculated from an acquired temperature; updates a control condition based on the reward, and determines an optimum action corresponding to the current state under the updated control condition, the control condition being a combination of a state and an action; and controls a target ring-shaped heater based on the optimum action.

A system for securely communicating information in a building management system (BMS) includes a plurality of HVAC devices communicably coupled via a network each HVAC device storing a copy of an HVAC data chain that includes a plurality of blocks linked sequentially. The plurality of HVAC devices includes a first HVAC device including a processing circuit configured to generate a first block comprising device data and send the block to at least a portion of the plurality of HVAC devices. The processing circuit is configured to receive a second block from one of the plurality of HVAC devices and solve the second block. The processing circuit is further configured to add the solved block to the HVAC data chain of the first HVAC device as the newest block and send the solved block to each of the plurality of HVAC devices.

A method to control a carrier fluid through a service line (5) of a conditioning and/or heating system (1). The service line includes a heat exchange unit (7), a flow regulator (8), temperature sensors (9; 9a, 9b) detecting a temperature difference (ΔT.sub.i) between the carrier fluid in a first section (5a) of the service line (5) upstream of said heat exchange unit (7) and carrier fluid in a second section (5b) of the service line (5) downstream of the same heat exchange unit (7). The method includes calculating a value assumed by a control parameter (Pc) which is a function of at least one or more values assumed by the temperature difference in the transition of the flow regulator from a first to a second operating condition, for then determining whether the value of the control parameter (Pc) is higher than a threshold (S).

Systems, apparatus and methods for providing personalized comfort to occupants of a conditioned space. A precision air device having a standalone controllable fan with directional nozzles is provided. The precision air device includes environmental and occupancy sensors, and communicates with a user device and with other precision air devices in the space. Application software installed on an occupant's user device enables the occupant to specify whether it is too cold or too warm within his or her personal space, or microzone. The collective demand of all microzones within a VAV macrozone is determined by a precision air aggregator to adjust a controllable VAV damper for that macrozone.

A temperature control system includes a fluid chiller, an air dryer, and a plurality of test stations positioned at remote locations from the fluid chiller and the air dryer. The fluid chiller is configured to generate a chilled fluid stream. The air dryer is configured to generate a dry air stream. Each local test station includes a heat exchanger and thermal control unit. The heat exchanger is configured to selectively cool the dry air stream with the chilled fluid stream to generate an output stream. The thermal control unit is configured to control distribution of the output stream to a local test site.

A temperature-controlled electronic apparatus, comprises: a circuit board; a plurality of electronic components, mounted on the circuit board in an arrangement to form at least one electronic circuit; a temperature sensor, configured to measure a temperature of the at least one electronic circuit; and a heat-generating component, configured to be controlled by a temperature control circuit, the temperature control circuit being configured to control an amount of heat generated by the heat-generating component in response to the temperature measured by the temperature sensor. The plurality of electronic components are arranged on the circuit board to lie on one of one or more paths, each path of the one or more paths being defined by a respective circle having a radius.

A method for balancing mass flow during production failure or insufficiency in a district heating network comprising a plurality of substations, each substation comprising at least one primary side connected to the district heating network for transferring heat between the district heating network and the substation, a secondary side connected to least one space heating circuit for heating at least one space connected to the substation, and an adjustable valve arranged between the substation and the district heating network, the valve (102) in each substation being controlled by a heat curve f defining a calculated supply temperature (Tsupply, calc) for the space heating circuit on the secondary side of the substation as a function of a measured outdoor temperature (Toutdoor). The method further comprises a step of heat curve compensation for each substation and population compensation for all substations in the population. The result is then used to control the valve in the respective substation.