Contact, Overview, Index Guideline heating and cooling Plexus Professor / Professor Plus Premum / Premax / Solus Architect Polaris I & S Plafond Podium Celo Cabinett Capella Carat Fasadium Atrium / Loggia Regula Drypac Lighting TEKNOsim 0 0.0 Lindab Ventilation A/S. All forms of reproduction without written permission are forbidden. is the registered trademark of Lindab AB. Lindab's products, systems, product and product group designations are protected by intellectual property rights (IPR).
0 Picture. Architect Circum, Luna and Prisma. Introduction Architect is a flexible and aesthetical, free hanging active chilled beam, designed to deliver a great flexibility and a perfect indoor climate. Equipped with the Lindab JetCone technology, along with adjustable air deflectors, the Architect beam offers the possibility of on-site adjustment, thereby allowing the beam to adapt to future changes in ventilation need. Worth noting Lindabs active chilled beams are Eurovent-certified and tested according to EN-. Key figures Length: Width: Height: Capacity: 00-000 mm (steps of 00 mm) - mm (design specific) mm 0 W Calculation setup Room temp: C, Water temp: - C, Air temp: C, Nozzle air pressure: 0 Pa, Air flow: l/s/m
0 Highly flexible active chilled beam The Architect delivers great cooling and ventilation in an architectural, free hanging wrapping. Equipped with the market leading Lindab JetCone technology, the Architect delivers a precision in air volume handling, only known to Lindab products. Combined with the unique Architect air deflectors, the Architect delivers a very high level of flexibility, as well as the possibility of adapting the beam to future demands, in a fast and easy fashion. Many mounting possibilities With the mounting options, Ceiling, Wall, or Free hanging, the Architect will fit any mounting need. Designed for visible mounting, the Architect can be fitted on any plane surface, or even freely suspended, with a perfect result. To hide the air duct and water pipes, the Lindab Architect can be delivered with a Connection Cover (Available in any length up to 00 mm), in order to perfect the overall design in the room. Air duct Copper pipes Freedom of design With three different designs, the Architect Luna, Prisma and Circum can fit any layout design. Project specific adaption based on the actual design of the building is also possible when using the Lindab Architect Luna, Prisma and Circum beam (special). As the beam consists of an independent body and an interchangeable faceplate, the initial installation of the beam can be carried out, before the design of the faceplate is decided. Detachable faceplate Adjustable Air deflectors Battery Picture. Architect Luna, Prisma and Circum is based on the induction principle.
JetCones The opening size of the nozzles can be adjusted, by operating the adjustment pins in each corner of the beam. The air distribution can also be adjusted, to achieve different amounts of air on either side of the beam, or to achieve an asymmetrical air pattern along the side of the beam. All thanks to our patent pending JetCone system. Architect Luna, Prisma and Circum are fitted with the JetCone air volume adjustment technology. The JetCone technology provides a market leading flexibility, with the possibility of adjusting the air diffusion pattern and air volume according to air pressure. Adjustment is made by changing the positions of the four adjustment pins. The adjustment pins can be set in any of the 0 steps, thereby offering a total of 0 different settings. The adjustment is done without any tools, making adjustments a fast and easy process. The fast adjustment system offers a unique opportunity within planning, as the air flow can be adjusted at any point after ordering. Air deflectors In addition to changing the air flow and air diffusion pattern, the Architect Luna, Prisma and Circum also offer the possibility of adjusting the air spread pattern. Using the individually adjustable air deflectors, the air spread pattern can be adjusted to optimize an almost endless list of scenarios, and thereby secure the best possible indoor climate in any situation. Adjustments are simply made by changing the position of the air deflectors, according to the desired degree of air spread. 0 0 Pos. Pos. Adjustment pins Pos. Pos. Nozzles JetCones Measuring point Picture. Architect Luna, Prisma and Circum, Lindab s JetCone air volume adjustment system.
0 Data Variants Architect is installed as an independent part of any ceiling or as a free hanging beam. Wall mounting also possible. Lengths: Architect is available in lengths from:. m to.0 m (in steps of 0. m). Water connection: The water connections for Architect are made of mm copper pipes. Air connection: Architect is supplied with a Lindab NPU - connection for Lindab Safe ducts. Design: Architect is supplied as standard with Slot perforation, 0% open area. Other perforation patterns are also available. Surface treatment: Architect is manufactured as standard from enamelled sheet metal. Accessories Delivered separately. Control: Refer to the chapter Regula. Suspension components: Threaded rods (0-00cm), or MHS hangers ( - 00 cm), for all beam lenghts. Colour The product is available as standard, in signal white RAL 00 or in pure white RAL 00, gloss value 0. Other RAL colours on request. Plus features Factory preinstalled. Heating: The product can be equipped with an additional water circuit in the battery to provide a heating function. Crosstalk protection: Crosstalk protection is build-in as standard. Integrated valve and actuator: A control valve, with variable Kv value, and an actuator can be pre-installed in the product. Regula Secura: Lindab's Regula Secura condensation protection can be installed in the product. Regula Connect: The product can be equipped with the Regula Connect connection card. Please see the Regula chapter for further information. Factory settings: Presetting of pressure (Pa) and air flow (l/s).
Dimensioning Cooling capacity air P a. Start by calculating the capacity required for the room, to keep a certain temperature. Lindab s TEKNOsim is an excellent tool for this.. Calculate which cooling capacity, or read in diagram, that is supplied by the ventilation air. Remaining cooling capacity needs to be cooled by the water circuit in Architect. The formula for calculating the capacity of the air: P a = q ma x c pa x t ra Size comparison by t r = C with: q a = Primary air flow rate P a [W] = q a [l/s] x. t ra [K] and P a [W] = q a [m³/h] x 0. t ra [K] Definitions: P a = Cooling capacity air [W] P w = Cooling capacity water [W] P tot = Cooling capacity total [W] q ma = Air mass flow rate [kg/s] q a = Primary air flow rate [l/s] c pa = Specific heat capacity air [,00 kj/kg K] t r = Room air temperature [ C] t wi = Water inlet temperature [ C] t wo = Water outlet temperature [ C] t ra = Temp. diff., room air and primary air temp. [K] t rw = Temp. diff., room air and mean water temp. [K] t w = Temp. diff. water circuit [K] e tw = Capacity correction for temperature e qw = Capacity correction for water flow P Lt = Specific cooling capacity [W/(m K)] 0 P a [W] Cooling Luftens capacity kyleffekt air 00 P a = q a, t ra t w [K] 0 00 00 00 00 00 0 0 0 0 0 0 Primary air Luftflöde flow rate q a [l/s] Diagram. Cooling capacity air P a as function of the primary air flow rate q a. If the air supply flow is l/s and the temperature difference of the room air and the supply air is t ra = K, then the Cooling capacity air of the air is 0 W.
0 Dimensioning Cooling capacity water P w Follow the instructions below to read off the effect from the diagram.. Calculate t rw.. Product length L minus 0. m, to obtain the active length L act.. Divide the primary airflow rate q a by the active length L act. Enter the result on the lower axis of diagram.. Follow the flow line to the right pressure, and then read off the specific cooling capacity P Lt per active metre.. Multiply the specific cooling capacity that was read off by t rw and active length L act. Example Cooling: What is the cooling capacity of a. m Architect with 0 l/s and pressure of 0 Pa? The room s summer temperature is assumed to be t r =.º C The cooling water temperature in/out of the Architect is /º C. Answer: Temperature difference: t rw = t r (t wi + t wo )/ t rw =. - (+) / = K Active length: L act =. m - 0. m = m q a / L act = 0 l/s / m = 0 l/(s m) Read off, from diagram : P Lt =. W/(m K). Cooling capacity: P w =. W/(m K) K m = W NB! The capacity diagram applies for the nominal water flow of nom = 0.0 l/s. To obtain the right cooling capacity P w for other flows, read off the capacity correction factor e qw from diagram, and then multiply the capacity, which is read off, by this factor as shown in example for heating. Specific P Lt [W/(m Cooling K)] kyleeffekt Capacity P Lt [W/(m K)],0,0,0,0 0,0,0,0,0,0 0,0,0,0,0 00 Pa 0 Pa 0 Pa,0 0 Pa 0,0 0 0 0 0 Primary air flow rate per active meter q a / L act [l/(s m)] a / L act [l/(s m)] Diagram. Specific cooling capacity P Lt as a function of primary air flow rate per active metre at nozzle pressures of 0, 0, 0 and 00 Pa.
Dimensioning Capacity correction for water flow e qw Example Heating: What is the heating capacity of a. m Architect with 0 l/s and pressure of 0 Pa? The room winter temperature is assumed to be t r = º C. The hot water temperature in/out of Architect is /º C. Answer: Temperature difference: Δt rw = (t wi + t wo )/ t r Δt rw = (+) / - = 0 K Active length: L act =. m - 0. m = m q a / L act = 0 l/s / m = 0 l/(s m) Read off, from diagram : P Lt =. W/(m K). Water capacity: P w =. 0 K m = W Use the calculated water capacity and calculate the water flow: = P w / (c pw x t w ) = / (00 x ) = 0.0 l/s The capacity correction e qw will then be 0. (see diagram ) and the new capacity: P w = x 0. = W Using the new heating capacity, a new water flow is calculated: = / (00 x ) = 0.0 l/s Read off the capacity correction e qw at 0. and calculate the capacity: P w = x 0. = 0 W Using the new heating capacity, a new water flow is calculated: = 0 / (00 x ) = 0.0 l/s Seeing that the flow is near stabile at this point in the calculation, the heating capacity is calculated to be 0 W. 0 Capacity correction e qw..0 0. 0. 0. 0. 0. Cooling Heating 0. 0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0. Diagram. Capacity correction e qw for water flow for both cooling and heating. Water Flow Rate [l/s]
Pressure drop in water circuit, cooling [l/s] Water flow rate 0, Lengths [m],,,, 0, 0,0 0,0 0, 0, Minimum permitted water flow=0.0 [l/s] Diagram. Pressure drop in water circuit, cooling. 0 0 0 Pressure drop Δp w [kpa] 0 Example Cooling: Architect. m, which provides an output of W. t w = K = P w / (c pw t w ) = W / (00 Ws/(kg K) x K) = 0.0 l/s The pressure drop in the water circuit in diagram is read off as Δp w =. kpa. Pressure drop in water circuit, heating [l/s] Water flow rate 0, Definitions: = Water flow rate [l/s] P w = Cooling capacity water [W] c pw = Specific heat capacity water [00 Ws/(kg K)] Δt w = Temperature difference water circuit [K],,,, Lengths [m] 0, 0,0 0,0 0, 0, Minimum permitted flow=0.0 [l/s] 0 0 0 Pressure drop Δp w [kpa] Diagram. Pressure drop in water circuit, heating. Example Heating: Architect. m, which provides an output of 0 W. t w = K = P w / (c pw t w ) = 0 W / (00 Ws/(kg K) K) = 0.0 l/s The pressure drop in the water circuit in diagram is read off as Δp w = 0. kpa. Definitions: = Water flow rate [l/s] P w = Heating capacity water [W] c pw = Specific heat capacity water [00 Ws/(kg K)] Δt w = Temperature difference water circuit [K] 0
Dimensions, weight & water content 0 Architect Luna 0 Architect Luna ± 0 0 Architect Prisma 0 Architect Circum Figure. Architect's different versions. 0 Luna Prisma Circum Ø Width, mm Height, mm Product length undersize, mm 0* 0* 0* Weight, kg/m Water content, l/m cooling Water content, l/m heating 0.0 0.0 0.0 0. 0. 0. * The face plat extends mm beyond the end gables, on each side. Table. Dimensions, weight and water content. 0 Figure. Architect Luna, Prisma and Circum, suspension / dimensions. ± 0
Couplings & connections Architect is supplied in lengths from.m to.0 m, in steps of 0. m. The connection dimension is mm for the water and mm for the air for Architect Luna, Prisma and Circum. Architect Luna, Prisma and Circum is available with a large number of coupling options. This is how to find the designation, for the coupling option you require: Step. Indicate the position for the ventilation connection. Step. Indicate the position for the pipe connection. IN OUT Examples of designations Below are examples of common coupling options: Type A has a horizontal air connection at the end, and a horizontal pipe connection at the same end of the beam. Vent. Top view Pipe Top view Cooling Figure. Coupling options A and B. 0 A B OUT IN IN OUT Pipe Top view Heating OUT IN Figure. Coupling and connection options.
Connection dimensions, cooling Ø 0 0 Ø 0 ±0 Figure. Architect Luna, Prisma and Circum, cooling. Dimensions for the parts. Total width and length for the respective models vary (see table ). 0 Connection dimensions, heating 0 Ø Ø ±0 Figure. Architect, heating. Dimensions for the parts. Total width and length for the respective models vary (see table ).
Sound effect pt [Pa] 00 Architect L =.-.0 m 0 0 00 0 0 0 0 0 0 0 0 pt [Pa] 00 0 00 0 0 0 0 0 0 0 q V [l/s] 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 00 0 00 0 Diagram a+b. Sound effect level L WA at JetCone setting --- for Architect. 0 0 0 LWA db(a) 0 L WA db(a) q [m /h] V q V [l/s] q V [m /h] Architect L =.-.0 m
Dimensioning Pressure drop in air connection Table shows the pressure drop in the connection. After calculating the necessary pressure for the supply air beam, add the connection pressure drop to the selected static pressure in the nozzles. Table. Air pressure drop in the connection to Architect. Sound data Hz Jetcone Position Internal sound dampening L 0 00 000 000 000 000 db Table. Architect.m position, internal sound dampening. Noise level L woct For calculation of the noise level Architect Air flow (l/s) 0 0 0 0 Pressure drop (Pa) Correction C oct (db) Octave band, average frequency (Hz) L =.-.0 m Hz 0 00 000 000 000 000 db - - - - - -0 - Correction C oct (db) Octave band, average frequency (Hz) L =.-.0 m Hz 0 00 000 000 000 000 db 0 - - - - - - Table a+b. Architect's noise levels L woct for each octave band in the beam, are calculated by adding the corrections C oct from the table above to the sound power level L wa db(a). The noise levels are calculated using the following formula: L woct = L wa + C oct 0
0 Control Lindab offers control equipment that is very simple to use. To avoid the heating and cooling being activated at the same time, the system is controlled sequentially (Regula Combi). For the technical data, refer to the chapter Regula. Designations Product/Version: Architect Luna, Prisma, Circum Connection diam. water, [mm]: Connection diam. air, [mm]: Coupling options: A, A, A, A B, B, B, B Length, [m]:. -.0 m in steps of 0. m Air quantity, [l/s]: - l/s Nozzle pressure, [Pa]: 0-0 Pa Distribution profile: Standard Medium Long Plus features: See page Order code Product Architect Luna A. 0 Type: Luna, Prisma, Circum Water connection: mm Air connection:, x Connection type: A, A, A, A, B, B, B, B Product length:. m -.0 m (in steps of 0. m) Static nozzle pressure (Pa): 0-0 Pa Air volume (l/s): - l/s Programme text for visible installation. Adjustments to air flow and spread pattern must be possible without tools. Air volume regulation should be as fluent as possible, allowing as many air volume options at any specific air pressure between 0 Pa and 0 Pa. Only linear air flow regulation can be accepted. s from Lindab Qty Product: Architect Luna---A-. m 0 Air volume: l/s Nozzle pressure: 0 Pa Distribution profile: Medium ( ) Plus features: Drypac Regula Secura Cooling control valve Cooling actuator Accessories: Regula Combi: 0 Product: Architect Circum---B-. m 0 Air volume: 0 l/s Nozzle pressure: 0 Pa Distribution profile: Standard Plus features: Drypac Heating Regula Secura Cooling control valve Cooling actuator Heating control valve Heating actuator Aerator Accessories: Regula Combi: 0