DOWNLOAD CATALOGUE     SEE VIDEO Highly developed casing form guarantees optimalexchanger surface exposition while hiding all structuralelements. The light and clean casing lines, combined with auniversal color palette, provide for harmoniousadaptation to every room type. Our patented locking system guarantees a durable andprecise fit of all casing elements. Made of highest-class ABSwith an anti-UV pigmentaddition, the casing is char-acterized by high mechanicalstrength, durability andresistance to high tempera-tures. The material usedguarantees unchangeableesthetic and easy-cleanproperties, guaranteeinglong-term durability certifiedby a lifetime warranty for thecasing. Optimized profile and increased blade surfaces guarantee low usage costs and quiet operation. The EC motor option guaranteesmaximum engine efficiency at reduced rotations.Step-less rotation regulation is now available for EC motors. The availability of high-efficiency,three-speed AC motors andenergy-saving EC motors providesfor optimal match of operationalparameters of each device whilemaintaining minimum electricityconsumption levels.

The device is environmentally-friendly.100% of materials used can be recycled. * maximum speed 0.5 m/s Each VOLCANO air heater pack has a printed templatepresenting the spacing of boreholes and a leveling line,which facilitate the mount of the console to the wall.Simply cut the template out of the cardboard lidand proceed to assembly. Check how we improved an offer of regulatorsARW dedicated to air heaters VOLCANOto provide better work of our devices on objects. Check parameters     Adjust regulator Call center 0 800 559 661 Immersed electrode humidifiers are less expensive to purchase; operate on drinking water (not completely demineralised or softened); require the periodical replacement (or cleaning) of the cylinder; feature modulation suitable for comfort or industrial applications, without extreme requirements. Electric heater humidifiers humidity must be controlled precisely (museums, laboratories, cleanrooms); the quality of the water is not constant or is problematic (for example, aboard ships);

periodical maintenance needs to be minimised (using demineralised water). Gas-fired steam humidifiers there are high humidification loads (heavy-duty applications) the cost of gas is lower than electricity and consequently running costs need to be kept down the user is willing to accept a higher initial investment to obtain ongoing savings over time Centralised steam distributors minimum absorption distance: the outlet of steam through continuous slits (rather than through nozzles, as in most of the competing systems) creates a thin layer of steam that flows uniformly from both sides of central air conditioning unit repairthe distributor, creating a large surface of contact with the air, allowing a minimum absorption distance (typically half the distance of conventional systems); 3 ton hvac unit costminimum losses due to condensation: the distributors are coated with a layer of very high tech ceramic insulation (deriving from aerospace applications), which reduces by up to 90% the losses due to condensate and the heating of the surrounding air; types of hvac systems for residential

no emission of droplets of condensate: the steam distributors trap and return any droplets of condensate back to the centre of the pipe, where these evaporate again. Adiabatic humidifiers for AHU/ducts and rooms very low electricity consumption: high pressure systems need less than 4 Watts per kg/h of capacity, against the 750W of steam humidifiers high capacity: the capacity can range from just a few kg/h (for example, humiSonic has a minimum capacity of 0.5 kg/h) to thousands of kg/h (humiFog) very low maintenance, in particular when supplied with demineralised water Centrifugal humidifiers Ultrasound humidifiers Very low power consumption Use of demineralised water: prevents problems due to bacteria and other contaminants. Dual effect: humidification, due to the adiabatic effect, ensures simultaneous cooling of the air, with a consequent decrease in refrigerant compressor running time. Finely atomised water: particles with a diameter of a few microns are easily and quickly absorbed by the air.

Compressed air and water atomisers the control cabinet, fitted with electronic controller; special atomising nozzles that can be installed in an AHU/duct or directly in the room being humidified/cooled; manifolds for installation in the duct; UV lamp sanitation system and protection filters. Modeling of Air handling Unit for Wireless Monitoring August 15, 2014 through P3 Awards: A National Student Design Competition for Sustainability Focusing on People, Prosperity and the Planet (2014) The main goal of this project is to achieve a reduction in energy consumption through air handling unit (AHU) system performance improvement while also considering occupant comfort level. The objectives are to: 1) identify the key parameters of the AHU that can be efficiently, accurately, and thoroughly enhanced in a building’s energy assessment; 2) develop the wireless energy performance and consumption monitoring system (WEPCMS); and 3) improve energy efficiency with reference to ASHRAE Standard 90.1-2010, Energy Standard for Buildings.

The project will be conducted by students under faculty supervision (PI) of the IUPUI Industrial Assessment Center (IAC). The project will consist of two phases. Phase I: The wireless monitoring system, which will enable remote, real-time, sub-system monitoring, will be created at IUPUI. Phase II: The selected air handling unit (AHU) will be continuously monitored in real-time; the data will be analyzed using the algorithms developed for the system. The process model of the AHU will be developed and the major parameters will be monitored and display remotely. Best-practices will be recommended based on the collected data. Phase I: Development of the WEPCMS The WESPCMS will operate at three levels. The top level resides in a control room equipped with computer and smart controller. The middle level will be in the building where the sub-system is located. It has a wireless mesh network that consists of a PAN coordinator and at least one Router Repeater. The third level will be at the sub-system, consisting of various sensors for measuring key data characterizing system performance and energy consumption.

Many third party devices have already been qualified to work with the wireless system for digital data transmission. The system has the sensors to collect performance data. The data will be sent wirelessly to the PAN coordinator directly or through a Router Repeater. The data will be further pushed to the smart controller via Ethernet and be stored in the computer. The sub-system can also be monitored real-time using IP cameras. Actions can be taken through the system to remotely control the sub-system if needed. The data from these sensors will be analyzed for performance evaluation and energy consumption. Algorithms will be developed specifically for analyzing sub-system data. Software will be written for implementing the algorithms, tabulating the results, and displaying them on a dashboard. This project requires both hardware and software development. Phase II: Implement WESPCMS on an Air Handling Unit We have identified a sub-system and an Air Handling Unit (AHU) in Science and Engineering building as the system for this pilot project.

This AHU is a large energy consumption unit and has been in service for 23 years. The performance of the unit has never been evaluated. This phase will be completed in the following steps. Step 1: Establish the energy consumption and performance baselines Step 2: Development of a model to link the system performance to the energy consumption Step 3: Develop control strategies and simulate the performance virtually (this part will be covered in the second phase of project) The expected outcomes will be: 1) identification of the key parameters of AHU performance that impact a building’s energy consumption; and 2) modeling the energy consumption process and develop a control algorithm strategy for energy improvement. The result will be the air handing unit with identification of dominates parameters. The system will have continuous data collection for further evaluation. An optimized control strategy can be developed during second phase of the grant after successful completion of this project.