Contact, Overview, Index Guideline heating and cooling Plexus Professor / Professor Plus Premum / / Solus Architect Polaris I & S Plafond Podium Celo Cabinett Capella Carat Fasadium Atrium / Loggia Regula Drypac Lighting TEKNOsim 0.0 Lindab Ventilation. 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).
Use Lindab's supply air beam can be used for cooling, heating and ventilation. Water valves, actuators, Regula Secura, Regula Combi and Regula Connect can all be built into the beam. Installation I-0 is installed into a false ceiling, and can be suspended by hangers or threaded rods. As standard is delivered for a 00 x 00 T false ceiling. can also be delivered with a variety of different Clip-in options, making the beam suitable for other types of false ceilings. Worth noting features the Lindab JetCone, an innovative way of regulating the air volume. The air volume can easily be adjusted without having to worry about pressure and noise issues. The Angled Nozzle system secures a perfect air spread pattern, available in a number of factory preset angles. As a plus feature the Lindab AirGuide system offers readjustable air spread pattern control. The chilled beam is fully integratable with the Lindab ehybrid solution and together they provide an optimal energy efficient solution. Lindabs active chilled beams are Eurovent-certified and tested according to EN-. Key figures Length: Width: Height: Capacity: 0, 0, 00, 000 mm 00 mm (ceiling adaption available) 00 mm 0 W Calculation setup Room temp: C, Water temp: - C, Air temp: C, Nozzle air pressure: 0 Pa, Air flow: l/s/m
Optimal functions Despite the product's small external dimensions, the construction makes it possible to achieve a high cooling capacity. is Lindab's highest performing supply air beam designed to meet extra high cooling demands. is based on the induction principle. Ventilation air is released through the nozzles into a dispersal zone, thereby creating a low static pressure. The low pressure causes the warm air from the room to be induced into the ventilation air through the battery. The volume of the warm indoor air is two to seven times that of the ventilation air. The air is cooled as it passes through the battery, which consists of aluminium fins with copper pipes filled with cold, running water. The heat from the room is absorbed through the aluminium fins and then transferred through the copper pipe to the water circuit and goes further to a central cooling unit. can be delivered with an exhaust air valve, on request. Air duct Copper pipes Cooled air Warm indoor air Actuators Air duct Copper pipes Detachable faceplate Picture. is based on the induction principle. JetCone and Angled Nozzles 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. The Lindab Angled Nozzles system successfully combines the Jetcone air volume adjustment with a preset air spread pattern. The combination of the Jetcone and the Angled Nozzles systems results in reduced throw lengths and optimized air volume regulation. The design is made to secure the coanda effect and a fan-shaped air pattern. The adherence of the air to the beam already occurs at the JetCone opening. Then, due to the coanda effect, the air follows the side of the beam towards the ceiling. Coanda effect Battery
Hygiene Everything is accessible for service The faceplate is simple to lower or remove. The faceplate is kept in place by four cotter pins. If two of the cotter pins, on one of the long sides of the faceplate are removed, the faceplate will open and hang from the other two pins. For complete removal, please see the installation instruction. When the faceplate is lowered or removed, the battery is accessible from below (see picture ). Construction is power is Lindab's high performing supply air beam, giving the highest cooling capacity to be used in rooms with substantial cooling requirements. In terms of appearence looks like Premum and can therefore preferable be used in alternation with Premum beams and thus provide an architecturally uniform appearance in the room. is developed and designed to achieve a high degree of flexibility. The standard with Angled Nozzles and JetCone allows the adjustment of air diffusion, air volume and air pressure. The beam equipped with the plus feature Airguide, makes it possible to easily change the air spread pattern. The water pipes are made of copper. Nevertheless, the water should be oxygen-free to prevent corrosion. Picture. When the faceplate is lowered or removed, the battery are accessible from below. AirGuide system is shown in picture (plus feature).
Initial settings Adjustment JetCone is delivered as standard with Lindab s JetCone air volume adjustment system. The JetCone System makes a very flexible product with possibility of adjusting air diffusion, air volume and air pressure. Adjustment is made by setting the four adjustment pins into different positions. The adjustment pins can be set in any of the steps, thereby offering a total of 0 different settings. The adjustment is done without any tools, which makes it very fast and easy to adjust the air pattern, air volume and air pressure. The fast adjustment system gives an opportunity within planning, since the product choice can be made in an early stage and the products can be drawn into the planning of the project even though the planner do not have all the data normally required to select a suitable beam. Presetting Angled Nozzles To achieve a desired air spread pattern the beam is delivered with the Angled Nozzles air distribution system. The Angled Nozzles are a simple yet effective way of creating a divergent air spread pattern without the capacity issues normally related to an air deflector system. The Angled Nozzles can be delivered preset in one of the following standard settings: 0 (default setting) 0 In order to meet special demands, the Angled Nozzles can be delivered in other configurations than the ones mentioned above (picture ). For more information, please contact Lindab. NB! Please note that the Angled Nozzles are manufactured in a fixed position (default 0 ) and cannot be retrofitted or changed. Picture. Different settings for AirGuide (plus feature). JetCones. Adjustment pins 0.. Position. Max open nozzle, 0% air flow. Position 0. Max closed nozzle, 0% air flow.. Nozzles Picture. Lindab s JetCone air volume adjustment system. Example: A number of beams are installed in an open-plan office. A separate office is to be fitted into the room. If the climate is to be optimal, the air volume and air distribution needs to be adjusted on the beam that will be built into the new room (see picture ). If the air has to be directed in a specific direction, it is also possible to adjust an asymmetrical distribution pattern (see picture ). For more information please go to www.lindqst.com. Picture. A separate office is to be fitted into the room. If the climate is to be optimal, the air quantity and air volume need to be adjusted for the beam that will be built into the new room.
Data Variants I-0 and I- are installed as an integrated part of a false ceiling, where the beam is fitted on top of a standard T support bar. X-0 is delivered for mounting below a false ceiling, as an integrated part of a ceiling tile system, with concealed T-bar. Lengths: is available in lengths from: I-0, I- and X-0:. m,. m,. m and.0 m. JetCone: The JetCone is standard feature. The factory settings will be done according to desired pressure (Pa) and primary air flow (l/s) and can be changed easily on site. Angled Nozzles: The Angled Nozzles are manufactured in a fixed position and cannot be retrofitted or changed (default is 0 ). Other settings on request. Water connection: The cooling water connections for are made of mm or mm (Optional), copper pipes. Heating pipes are mm. Air connection: is supplied with a Lindab NPU - nipple for Lindab Safe ducts. Design: is supplied as standard with a Slot perforation, with 0% open area. Other perforation patterns are also available. Surface treatment: is manufactured as standard from enamelled sheet metal. Colour The product is available as standard, in signal white RAL 00 or in pure white RAL 0, gloss value 0. Other RAL colours on request. Accessories Delivered separately. Control: Refer to the chapter Regula. Suspension components: threaded rods ( - 0 cm), or MHS hangers ( - 00 cm), for all beam lenghts. Plus features Factory preinstalled. AirGuide: The Lindab AirGuide system offers readjustable air spread pattern control. With a total of eight adjustment points (two points on each of the four deflector), and four different settings at each adjustment point, the AirGuide deflectors have different settings (Picture ). The adjustment is simply done by releasing a retaining clip in one end of the deflector. The deflector can then be adjusted to the desired setting and the retaining clip is refitted. These easy steps are then carried out for all the adjustment points that needs to be changed. The AirGuide will be pres-set (default is 0 - ) in the factory, If not any other setting is wanted and can be changed easily on side. Selection the AirGuide option will incur a capacity reduction of % for cooling and heating compared to the Angled Nozzles system. The AirGuide system is an alternative to the Angled Nozzles. Recommended settings are: 0 - (default, correspondend to 0 Angled Nozzles) 0 - (correspondend to Angled Nozzles) - (no corrosponded Angled Nozzles) 0-0 (special setting) NB! See page for Air patterns 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. Integrated regulation unit: It is possible to have Lindab's room regulator, Regula Combi, pre-installed in the product. The control panel is fully accessible through the faceplate. Please see the Regula chapter. 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), primary air flow (l/s), Angled Nozzles position (default 0 ) or spread pattern (if the AirGuide has been selected as plus feature). Exhaust air valve: can be delivered with build in exhaust.
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 heat load needs to be cooled by the water circuit in. 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] Minimum flow Please note that flows below the recommended minimum flow, can result in unwanted air in the water pipes. Exciding the nominal flows is not recommandable as the capacity gains will only be minimal. Pipe diameter Min flow Nominelt mm 0.0 l/s 0.0 l/s mm 0.00 l/s 0.0 l/s 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 air flow 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.. Calculate the temperature difference in water circuit Δt w and find the capacity correction factor e Δtw in diagram.. Multiply the specific cooling capacity P Lt that was read off by e Δtw, t rw and active length L act. 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)] P a [W] Cooling Luftens kyleffekt capacity air 00 P a = q a, t ra t ra [K] 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 of the air is W.
Example Cooling: What is the cooling capacity of a. m 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 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 = l/(s m) Read off, from diagram : P Lt = W/(m K). Diagram shows a capacity correction factor e Δtw : t w = t wi - t wr = C - C = K e Δtw = 0. Cooling capacity: P w = W/(m K) 0. K. m = W NB! The capacity diagram applies for the nominal water flow of q wnom = 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 calculated cooling capacity by this factor as shown in example for heating. Specific Cooling Capacity P Lt [W/(m K)] 0 0 0 0 0 0 0 0 0 Pa 0 Pa Pa 0 Pa 0 Pa NB! A reduction at up to % may occure, if the AirGuide has been selected. 0 0 0 0 0 0 0 q 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, 0 and Pa.,000,000 Capacity correction e Δtw,0000 0,00 0,00 0,00 0,00 Diagram. Capacity correction e Δtw as a function of t w. Only applies for cooling. t w
Dimensioning Capacity correction for water flow e qw Example Heating: What is the heating capacity of a. m 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 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 = l/(s m) Read off, from diagram : P Lt =.0 W/(m K). Water capacity: P w =.0 0 K. m = W Use the calculated water capacity and calculate the water flow: q w = P w / (c pw x t w ) q w = / (00 x ) = 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: q w = / (00 x) = 0.0 l/s Read off the capacity correction e qw at 0. and calculate the capacity: P w = x 0. = W Using the new heating capacity, a new water flow is calculated: q w = / (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 W. Capacity correction e qw..0.00 0. 0.0 0. 0.0 0. 0.0 0. 0.0 0. 0.0 0. 0.0 0. 0.0 0. 0 0.0 0. 0. Water Flow Rate q w [l/s] Diagram. Capacity correction e qw for water flow for both cooling and heating. Cooling Heating
Pressure drop in water circuit, cooling/heating [l/s] Cooling 0. 0. 0.0 0.0 0.0 0.0 0.0 0.0 0.0 mm mm Lengths [m], ø,,,0, ø,,,0 0.0 0 0 0 0 0 0 Pressure drop [kpa] [l/s] Heating mm Lengths [m]....0 0. 0. 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0. 0. 0. 0. 0. 0. 0. Pressure drop [kpa] Diagram. Pressure drop in water circuit, cooling and heating. Example Cooling:. m, which provides on output of W, mm pipes. t w = K, q w = P w / (c pw t w ) q w = W/(00 Ws/(kg K) K) = 0.0 I/s The pressure drop in the water is read off as. kpa. Example Heating:. m, which provides on output of W, mm pipes. t w = K, q w = P w / (c pw t w ) q w = W/(00 Ws/(kg K) K) = 0.0 I/s The pressure drop in the water is read off as. kpa. Definitions: q w = Water flow rate [l/s] P w = Cooling/heating capacity water [W] c pw = Specific heat capacity water [00 Ws/(kg K)] Δt w = Temperature difference water circuit [K]
p t [Pa] 0 L <. m Pos no: 0 L <.0 m 00 0 0 0 0 0 0 0 L W A db(a) q V [l/s] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 q V [ m /h] p t [Pa] 0 _> L. m Pos no: 0 L >,0 m 00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 00 Diagram. Sound effect level L WA and JetCone setting for. 0 0 0 0 L W A db(a) q V [l/s] 0 0 0 0 q V [ m /h] 00 0 0
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. Example : I 0---A-. with 0 l/s and static nozzle pressure of 0 Pa. This provides the necessary total pressure in the duct of 0 Pa + Pa = Pa. Air flow [l/s] 0 0 0 0 0 0 Pressure drop [Pa] 0 Table. Air pressure drop in the connection to I-0. Sound data Table. 's internal sound dampening. Noise level L woct For calculation of the noise level Internal sound dampening L Hz JetCone position 0 00 00 000 000 000 db Correction C oct (db) Octave band, average frequency (Hz) L. m Hz 0 00 00 000 000 000 db - - - - - - - Correction C oct (db) Octave band, average frequency (Hz) L >. m Hz 0 00 00 000 000 000 db - - - - - - - Table a+b. '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 Weight and water volume Weight, kg/m Water content, cooling, l/m 0. Water content, heating, l/m 0. Copper pipes, quality Pressure class Table. 's weight and water volume. EN - CU-DHP PN
Ventilation connections Inlet C Exhaust G A B Top view F E D H E A F B G C D H Figure. For A connection, is delivered with Lindab's standard nipple (NPU-). For B, C, and D connection, Lindab's elbow piece (BU 0 ) is included. Water connections Possible connections, air ( A, B, C, D ) and water (,,,,, ). A:,,,,, B:,,,,, C:,,, D:,,, Figure. Possible connections, water cooling and heating.
Connection,, or Figure. Placement of cooling and heating pipes ( mm). NB! When compression couplings are used, support sleeves must be applied. Connection or All copper pipeoutlets / inlets are labled to ensure correct connections. Connection A Connection B Figure. Examples of the most common supply air A and B variants. Go to next page to see overview of various water pipe connections. A B
lindab premax Valves & actuators Valve Actuator Figure. Valve with actuator mounted. Figure. Illustration of how the valve and actuator is placed inside the chilled beam, A example,. Dimensions Examples below show I-0 models with A air connection. For external dimensions, see next page. n Connection or Connection or 0 n 0 Connection or 00 00 0 0 Figure. I-0-A with possible water connections.
Suspension I-0 (I-) 0 0 A (I- = ) I-0: L = 0, 0, 00, 000 mm; A =,,, mm. I-: L = 0, 0, 00, 000 mm; A =,,, mm. L = Nominal length (order length) Figure. I-0 suspension, dimensions. Suspension components are not supplied as part of the standard package. X-0 0 A X-0: L = 0, 0, 00, 000 mm; A =,,, mm. L = Nominal length (order length) Figure. X-0 suspension, dimensions. Suspension components are not supplied as part of the standard package.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. 00 00 0,0m/s 0,m/s 000mm 000mm Air flow l/s/active m Air flow l/s/active m Figure. 00mm 0 00mm 00mm 0 00mm Figure. 00 00 0,0m/s 0,m/s 0,0m/s 0,m/s 000mm 000mm Air flow l/s/active m Air flow l/s/active m 00mm 0 00mm 00mm 0 00mm Figure. Figure. 0,m/s 0,0m/s Figure -. Air velocities between supply air beams at a separation of 00 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. 00 00 0,0m/s 0,m/s 0,0m/s 0,m/s 000mm 000mm Air flow 0 l/s/active m Air flow l/s/active m 00mm 0 00mm Figure. Figure. 0 00mm 0 00mm Figure -. Air velocities between supply air beams at a separation of 00 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa. 0 0,m/s 000mm 0,m/s 000mm Air flow l/s/active m Air flow l/s/active m 00mm 0 00mm 00mm 0 00mm Figure. Figure. Figure -. Air velocities between supply air beams at a separation of 0 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. 0 0 0,0m/s 0,m/s 000mm 0,0m/s 0,m/s 000mm Air flow l/s/active m Air flow l/s/active m 00mm 0 00mm Figure. Figure. 00mm 0 00mm 0 0 0,0m/s 0,m/s 0,0m/s 0,m/s 000mm 000mm Air flow 0 l/s/active m Air flow l/s/active m 00mm 0 00mm Figure 0. Figure. 00mm 0 00mm Figure -. Air velocities between supply air beams at a separation of 0 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa. 0
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. 0 0 0,m/s 000mm 000mm Air flow l/s/active m Air flow l/s/active m golvnivå floor 00mm 0 00mm Figure. Figure. 00mm 0 00mm 0 0 0,m/s 0,0m/s 0,m/s 000mm 000mm Air flow l/s/active m Air flow l/s/active m golvnivå floor 00mm 0 00mm 00mm 0 00mm Figure. Figure. Figure -. Air velocities between supply air beams at a separation of 0 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. 0 0 0,0m/s 0,m/s 0,0m/s 0,m/s 000mm 000mm Air flow 0 l/s/active m Air flow l/s/active m 00mm 0 00mm Figure. Figure. 00mm 0 00mm Figure -. Air velocities between supply air beams at a separation of 0 mm. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. 000 mm 000 mm 0 Vägg wall 00 mm 000 mm 000 mm Vägg wall 00 mm 000 mm 000 mm Figure. Figure. 0-0 00-0 000 mm Vägg wall Figure 0. 00 mm 000 mm 000 mm Figure -0. Air velocities below s supply air beam, where the air flow is l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. Air velocities on a shelf. 000 mm 0 0,m/s 000 mm Vägg wall 00 mm 000 mm 000 mm Vägg wall 00 mm 000 mm 000 mm Figure. Figure. Air velocities at wall / throw. 0-00 00-0 0,m/s 000 mm Vägg wall 00 mm 000 mm 000 mm Figure. Figure -. Air velocities below s supply air beam, where the air flow is l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. Air velocities on a shelf. 000 mm 0 0,m/s 000 mm Vägg wall 00 mm 000 mm 000 mm Vägg wall 00 mm 000 mm 000 mm Figure. Figure. Air velocities at wall / throw. 0,m/s 0-00 00-0 000 mm golvnivå floor Vägg wall 00 mm 000 mm 000 mm Figure. Figure -. Air velocities below s supply air beam, where the air flow is l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. Air velocities on a shelf. 000 mm 0,m/s 000 mm 0 Vägg wall 00 mm 000 mm 000 mm Vägg wall 00 mm 000 mm 000 mm Figure. Figure. 0-000 0-0 0,m/s 000 mm wall Vägg Figure. 00 mm 000 mm 000 mm Figure -. Air velocities below s supply air beam, where the air flow is l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. Air velocities on a shelf. 000 mm 0,m/s 000 mm 0 wall Vägg 00 mm 000 mm 000 mm Vägg wall 00 mm 000 mm 000 mm Figure 0. Figure. 00-0 0-00 0,m/s 000 mm golvnivå floor Vägg wall Figure. 00 mm 000 mm 000 mm Figure 0-. Air velocities below s supply air beam, where the air flow is 0 l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, The JetCone & Angled Nozzles systems used in guarantees the Coanda effect and a fan-shaped air pattern in all cases. The fan-shaped air pattern ensures air velocities in the living area that are half those obtained with a linear air pattern. The measurements shown below were made with a cooled supply air ( t room air supply air) of C and cooling in the water circuit ( t room air average water temperature) of C. Air velocities on a table. Air velocities on a shelf. 000 mm 0,m/s 000 mm 0 wall wall Vägg 00 mm 000 mm 000 mm Vägg 00 mm 000 mm 000 mm Figure. Figure. 000-00 0-0 0,m/s 000 mm wall Vägg Figure. 00 mm 000 mm 000 mm Figure -. Air velocities below s supply air beam, where the air flow is l/s per active metre. Standard air pattern profile (nozzles at a 0 angle). Nozzle pressure of 0 Pa.
Air patterns, Throw and air patterns 00 mm under the ceiling. 0 00 00 00 l/s / active meter Angled nozzles presetting: l/s / active meter Angled nozzles presetting: 0 Figure. 0 0 Figure. Default Setting Angled Nozzles (or AirGuide). Throw and spreading 00 mm under the ceiling. 000 Throw and spreading 00 mm under the ceiling. 0 00 00 l/s / active meter Angled nozzles presetting: 0 l/s / active meter AirGuide setting: 0º - 0º 0 Figure. Figure. Figure -. Throw lengths with l/s active meter at 0 Pa t = K t rw 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: I or X Type: 0, Connection diam. water, [mm]: or Connection diam. air, [mm]: Coupling options: A, B, C, D Coupling options, exhaust: E, F, G, H Water:,,,,, Length, [m]:. m,. m,. m and.0 m Plus features: See page Angled Nozzles: 0 (default),, 0 AirGuide: 0 - Order code Product I-0 A. 0 0 Type: I-0, I- I = Integrated, lay-in X-0 X = i.e. hidden T-bar, edge DS Water connection: mm, mm Air connection: Ø mm Connection type: A, A, A, A, A, A, B, B, B, B, B, B, C, C, C, C, D, D, D, D Product length:. m -. m -. m -.0 m Static nozzle pressure (Pa): Air volume (l/s): Programme text active chilled beam with adjustable airflow, for a given duct pressure. Air distribution must be adjustable between both sides of the beam and longitudinally, by a system like Lindab JetCone. The flow pattern must be fanshaped through the use of angled nozzles. Water and air connections must be flexible and accessible from below. s from Lindab Qty Product: I-0---A-. m 0 Air quantity: l/s Nozzle pressure: 0 Pa Plus features: AirGuide Regula Secura Heating Cooling control valve Cooling actuator Heating control valve Heating actuator Accessories: Regula Combi: 0 Product: I-0---A-.0 m Plus features: AirGuide Regula Combi Regula Secura Cooling control valve Cooling actuator Accessories: Tectite tool: 0