Contact, Overview, Index Guideline heating and cooling Plexus Professor / Professor Plus Premum / Premax / Solus Architect Polaris I & S Plafond Podium Celo Cabinett Capella Carat Atrium / Loggia Regula Drypac Lighting TEKNOsim 0 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 facade system is an efficient system designed to handle low air pressures. Typical environments where is used include, for example, schools, hospitals and offices. can be used for cooling, heating and ventilation. is supplied as standard with valves, flexible pipe connections and a connection card for the Regula Connect control system. Additional features that can be integrated into include, for example, Regula Combi and the Regula Secura condensation guard. Installation is placed along the facade, behind built-in window sills. is available both as a standard model and as a low model for use where space is critical. Worth noting is developed for an operating pressure of up to 0 Pa. utilises counter-flow heat exchange. The system is provided with a service hatch, which provides full access to the whole battery and helps maintain good hygiene. Lindab's facade system has been tested at the Technical Research Institute of Sweden (SP). Key figures Width: Height: Depth: Capacity: 00, 00, 00, 000, 00, 00 mm 00-0 mm 0 mm 0 W Calculation setup Room temp: C, Water temp: - C, Air temp: C, Nozzle air pressure: 0 Pa, Air flow: 0 l/s 0
0 Function is a facade system with a heating, cooling and ventilation functions. For installation there are supplementary parts for heating, cooling and ventilation (see under System Accessories). uses the supply air's driving power, which through induction creates a flow of air through the battery, thereby ejecting cooled or heated air from the system (see picture ). On the water side, the individual room temperature is controlled by an electronic control system, Regula Combi, with the heating and cooling in sequence. The control feature ensures that the heating and cooling are not activated at the same time. provides high cooling effects at operating pressures of 00 to 0 Pa. has been tested according to the V method at the Technical Research Institute of Sweden. Additional functions include a condensation guard, Regula Secura, which prevents condensation formation, and a service hatch that provides the maximum accessibility to the battery for cleaning and inspection. Design 's technical design provides the maximum output. The heating and cooling battery is installed to ensure counter-flow heat exchange between the incoming room air and the cooling water in the battery. Induction nozzles Cooling and heating battery Cooled/heated air Room air This technical solution provides high cooling effects, while allowing the supply cooling water temperature to be kept low, without condensation problems. 's end plates, sides and air duct are made from galvanized sheet steel. A service hatch is located on the front edge of the system. All of the heating and cooling battery is accessible for cleaning from both sides through this service hatch. When open, it also provides access to all the ventilation duct's intake nozzles. The battery has separate circuits for cooling and heating water. The circuits are made from copper pipe that has been expanded mechanically to ensure contact with the aluminium ribs. The battery is mounted horizontally and is easily accessible for cleaning. The water circuits are pressure-tested along their entire length to. MPa for pressure class NT 0. The cooling feed pipe is insulated against condensation. To protect the system further against condensation, a condensation guard can be installed. The condensation guard provides significantly increased security against condensation. The Regula Secura condensation guard is positioned next to the battery to detect the formation of moisture. If condensation does form, the cooling water circuit valve closes to prevent it. Then, it re-opens to detect what output can be achieved without condensation forming. The water pipes are made of copper. Nevertheless, the water should be oxygen-free to prevent corrosion. Regula Connect Basic Heating and cooling pipes Control valve and actuator Ventilation air Picture. uses the supply air's driving power, which through induction creates an air flow through the battery, thereby ejecting cooled or heated air from the system. 0
Hygiene is designed for easy cleaning and service. The service hatch provides unrestricted access to the system's battery both from above and below. On delivery, the system's battery is shielded with protective wrapping and the outlet with protective tape. This prevents dust and dirt from getting into the system before it is put into operation. Picture. Cleaning is easy with the service hatch on the front. Picture. installed without columns. Initial settings The facade system is supplied with the ordered airflow at a given air pressure. On-site adjustment is therefore not required. The Kv value of the control valves is preset at the factory (standard). If necessary, the airflow and pressure drop on the water side can also be adjusted on site. Picture. installed with columns. 0
Casing suggestions Lindab supplies the facade system without casing. Below are suggestions for three types of casing with different types of wood. When is installed with columns, the whole system is moved away from the facade so the piping and trunking pass in front of the column, see figure and. 0 Standard Low 0 Electrical cable duct Electrical cable duct Water pipes 0 0 00 0 Water pipes 0 00 0 00 Air duct Ø00 Ø0 Ø00 Air duct Ø00 Ø0 Ø00 0 Min. 0 mm 0 0 Measurements for standard and low facade systems, with a view to adjusting the casing. Min. 0 mm 0 0 Floor Figure. Figure. Picture. Casing with a worktop fitted with a hatch that is lifted to provide access. Picture. Casing with fixed worktop and detachable hatch on front side. Picture. Casing with fixed worktop and visible electrical cable duct.
Control system The room temperature control system with its pre-fabricated cabling is easy to adapt to varying room sizes and to changes in the room divisions. Operating voltage V AC (see picture ). Actuators: Delivered as Normally Closed. Normally Open actuators available on request. Time for opening and closing: approx. min. Regula Connect Basic: Connection card with connectors for mains cables, thermostat cables and terminal blocks for actuator cables. The card has alternatives for the mains cable outputs, so the control signal can be transmitted to the next system in both directions or terminated at a wall. A transformer is also connected to a free port. The connection card can be accessed by lifting the system grill (applies for standard systems). Cabling: The system consists of a device cable, extension cable and thermostat cable. The cables are prefabricated and equipped with error-proof connectors (sold separately). Regula Combi: Regula Combi is a zone controller for integrated installation in products or directly on the wall. Regula Combi has a built-in temperature sensor and can use input from presence sensor, CO sensor, condensation detector and an external temperature sensor. Transformer: primary 0V, secondary V AC. Regula Secura: The Regula Secura condensation guard cuts the power to the actuator if condensation is detected (plus feature). For more information about the control systems, refer to chapter Regula. Versions Standard systems Lengths: 00, 00, 00, 000, 00 and 00 mm. Depth: mm Duct diameter: 0 mm Height: 00 mm, with room for electrical ducting, exclusive of worktop Options Duct diameter: 00 mm Height: 0 mm Duct diameter: 00 mm Height: 0 mm Low model Duct diameter: Height: Duct diameter: Height: Duct diameter: Height: Switching over control cables REGULA CONNECT BASIC 00 mm 00 mm 0 mm 0 mm 00 mm 00 mm When moving, building new or removing existing partitions, the control system can be reconnected (see picture ). This is to allow the control centre to regulate the products in the room where it is installed. The device cable consists of four conductors, two for the supply voltage and two for the control signal to the heating and cooling actuators. The figures refer to the picture below. Connectors for heating output devices, such as heating circuit actuators. Connectors for cooling output devices, such as cooling circuit actuators. Connector for power and communication input from Regula Combi. - Connector for power and communication link between one or more beams. Connector for direct power via external transformer. 0 REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB REGULA CONNECT BASIC N = Neutral L = Load S = Signal Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB Picture. When existing partition walls are moved, the control system can be reconnected. Trafo H C H C H C H C H C H C Heating out - S Heating out - N Heating out - L Cooling out - S Cooling out - N Cooling out - L Heating in - S Cooling in - S Supply out - N Supply out - L Heating link_s Cooling link_s Supply link - N Supply link - L Heating link_s Cooling link_s Supply link - N Supply link - L Supply in - N Supply in - V - L LINDAB N = Neutral L = Load S = Signal
0 grills Galea is the name of Lindab's new grills for. The grills have arched ribs for the optimum air distribution. Galea is placed in the casings for and is made from aluminium. The grills are available in lengths from 00 to 00 mm. They are available in two colours, white-coated and natural-anodised. Designation Galea grill 00, nature Galea grill 00, nature Galea grill 00, nature Galea grill 000, nature Galea grill 00, nature Galea grill 00, nature Galea grill 00, white Galea grill 00, white Galea grill 00, white Galea grill 000, white Galea grill 00, white Galea grill 00, white Size dim: x mm dim: x mm dim: x mm dim: x mm dim: 0x mm dim: x mm dim: x mm dim: x mm dim: x mm dim: x mm dim: 0x mm dim: x mm
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. 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 [W] P a [W] Luftens Cooling kyleffekt capacity air P a P = = q a qx p x., x x t ra t t ra [K] 00 0 00 00 00 00 00 0 0 0 0 0 0 Primary air flow Luftflöde 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 (room average water). Product length L minus 0. m, to obtain the active length L act.. Divide the airflow 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. P Lt Lt [W/(m K)] Specific Cooling Capacity 0 0 0 Example Cooling: What is the cooling capacity of 000 with l/s and pressure of 0 Pa? The room's summer temperature is assumed to be.ºc. The cooling water temperature in/out of is /ºC. Answer: Temperature difference: t rw = t r (t wi + t wo )/ t rw =. - (+) / = K Active length: L act =.0 m - 0. m = 0. m q a / L act = l/s / 0. m =. l/(s m) Read off, from diagram : P Lt = 0. W/(m K) Cooling capacity: P w = 0. W/(m K) K 0. m = W 0 Pa 0 Pa 00 Pa 0 Pa 0 0 00 Pa 0 0 0 0 0 0 /metre qq a a // L act act [l/(s m)] Diagram. Specific cooling capacity P Lt as a function of airflow per active metre at nozzle pressures of 00, 0, 0, 00 and 0 Pa.
Minimum airflow at different pressures System size Pressure (Pa) 00 00 00 000 00 00 00 0 0 0 00 0 0 Table. Minimum airflow at different pressures for the air from to reach the ceiling with a room height of.0 m. Temperature difference t between mean water and room is 0 C. Heating natural convection System size t 00 00 00 000 00 00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 00 00 0 Table. The system's heat emission through natural convection in W (no supply air) for respective sizes and temperature difference between the room temperature and the mean temperature of the heating water. 0
heating effect sound Effect according to the V method The tabulated data for the cooling effect is measured according to the V method at the Technical Research Institute of Sweden. The test measurements are made on the 00 system at 00 Pa, 0 Pa and 0 Pa, with casing and grill mounted on the system. Operating pressure at 00 Pa (0- l/s) The V method means that the room temperature is measured at. m above floor, i.e. the temperature in the occupied area. The V method gives a lower effect value compared to conventional measurements. This is because conventional measurement methods use the temperature of inlet air to the facade system to calculate the effect values. Inlet air has a lower temperature than that in the occupied area. 0 * Room height should be less than. m. 0* 00 < 0* 00 0 0 < 00 < * 00 0 0 < * 00 < 00 0 < 00 0 < * 000 0 < 00 00 00 0 0 < 000 0 < * 00 0 0 0 0 < Table -. Table -. The systems' cooling and heating effect in W, at an operating pressure of 00 Pa, an airflow of 0 to l/s and different t. The system's noise sound generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area.
heating effect sound Operating pressure at 00 Pa (-0 l/s) * Room height should be less than. m. 00 < 000 0 0 0 0 0 < * 00 0 0 0 0 0 0 0 < 0 000 < 0 00 0 00 < 00 0 0 0 < * 00 0 < 0 00 0 < 0 00 0 0 < 0 00 0 0 0 0 < Table -. The systems' cooling and heating effect in W, at an operating pressure of 00 Pa, an airflow of to 0 l/s and different t System's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area. 0
0 heating effect sound Operating pressure 0 Pa (0- l/s) * Room height should be less than. m. 0 00 0 0 < 0* 00 < 0* 00 0 0 0 0 0 < 00 0 < 00 0 < * 00 < * 000 0 0 0 < 00 0 0 0 0 0 < 00 0 0 0 0 0 < 000 0 0 0 < * 00 00 < 00 0 < 00 < 000 < * 00 0 0 0 0 < Table -. The systems' cooling and heating effect in W, at an operating pressure of 0 Pa, airflow of 0 to l/s and different t The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area. 0
heating effect sound Operating pressure 0 Pa (-0 l/s) * Room height should be less than. m. Table -0. The systems' cooling and heating effect in W, at an operating pressure of 0 Pa, airflow of to 0 l/s and different t. The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area. 00 0 < 000 < 00 < 000 0 < 00 0 < 00 0 0 < 0 00 0 0 0 < 0 00 0 < 0 00 00 < 0 000 0 < 0 00 0 < 0* 00 < 0 00 0 0 0 < 0
0 heating effect sound Operating pressure at 0 Pa (0- l/s) * Room height should be less than. m. 0 00 0 < 0 00 0 < 0* 00 < 0* 000 0 0 < 00 < 00 00 00 00 < 00 0 0 0 0 < * 000 0 0 < * 00 0 0 0 0 < 00 0 0 00 0 0 0 0 0 00 0 < 00 0 0 0 0 0 0 00 0 < 00 0 < 000 0 < * 00 0 0 0 < 00 0 0 < 00 < 000 0 0 0 0 0 0 00 0 < 00 0 0 0 < Table -. The systems' cooling and heating effect in W, at an operating pressure of 0 Pa, airflow of 0 to l/s and different t. The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area.
heating effect sound Operating pressure at 0 Pa (-0 l/s) 00 0 0 0 0 0 < 00 0 0 < 000 0 0 < 00 0 < * 00 0 < 0 00 0 0 0 00 < 0 000 0 < 0 00 0 0 00 0 < 0* 00 0 0 0 0 0 0 0 < 000 0 < 00 0 0 0 0 < 00 0 0 < 0 00 < 0 00 0 0 0 0 00 < 0 00 00 < Table -. Systems' cooling and heating effect in W at operating pressure of 0 Pa, air flow of to 0 l/s and different t. The system's inherent sound generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area. 0
0 heating effect sound Operating pressure 00 Pa (0- l/s) 00 0 0 < 00 0 < 00 0 0 < 000 < * 00 0 0 0 0 < 00 0 < 00 0 0 < 00 0 0 0 0 00 < 000 00 < 00 0 0 0 < 0 00 < 0 00 0 0 0 0 < 0 00 0 0 < 0* 000 0 0 0 0 0 0 0 < 00 < 00 0 0 < 00 0 0 < 000 0 < 00 0 0 00 0 < * 00 0 < Table 0-. The systems' cooling and heating effect in W, at an operating pressure of 00 Pa, airflow of 0 to l/s and different t. The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area.
heating effect sound Operating pressure 00 Pa (-0 l/s) 00 0 0 < 00 0 00 0 0 < 000 00 0 < 00 0 < 00 0 0 0 0 < 0 00 0 < 0 00 < 0 000 0 < 0 00 0 0 0 0 0 < 0 00 0 0 0 < 00 0 0 0 0 0 0 00 0 < 000 < 00 < 00 0 0 0 < 0 000 0 0 < 0 00 0 0 0 0 < 0 00 0 0 0 < Table -. The systems' cooling and heating effect in W, at an operating pressure of 00 Pa, airflow of to 0 l/s and different t. The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m Sabine equivalent sound absorption area. 0
heating effect sound Operating pressure 00 Pa (0 l/s) 0 00 0 0 < 0 00 0 < Table. The systems' cooling and heating effect in W, at an operating pressure of 00 Pa, airflow of 0 l/s and different t. The system's inherent noise generation in L A db(a) for a system with casing in a room with 0 m² Sabine equivalent sound absorption area. 0
pressure Example : What is the sound pressure in the first system of several systems connected in series? The airflow to the first unit is 00 l/s. The duct diameter (Ø) is 0. Answer: Read off the sound pressure from diagram, Inherent noise generation in the first system. The value is db(a). Add the value to the system's sound pressure - db(a). Read off the increase from diagram, Logarithmic addition of two s, and add it to give a higher sound pressure. Diagram shows a value of approx.. db(a), which must be added to the higher, db(a). Round off to a whole db(a) value. The result is a total sound pressure of db(a). [db(a)] Ljudtrycksnivå pressure Ø 0 0 0 Ø 00 0 0 0 0 00 00 00 Totalflöde flow [l/s] Diagram. Inherent noise generation in the first system. pressure with 0 m² Sabine attenuation. pressure 0 [db] Ökning Increase som to skall be adderas added till to den the högre higher nivån,0,,0,,0 0, 0 0 0 Difference Skillnad between mellan the nivåer s som to skall be adderas added [db] Diagram. Logarithmic addition of two s.
0 Internal sound dampening Frequency (Hz) Size 0 00 000 000 000 000 00 00 00 0 000 0 0 0 00 0 00 0 Table. Total sound power reduction from connecting duct to the room, including end reflection. Weight and water volume Weight, kg Ø00 duct Weight, kg Ø0 duct Weight, kg/m Ø00 duct Water content, cooling, l/m Water content, heating, l/m Copper pipes, quality 00 Table 0. Weight and water volume. 00 00 000 00 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. EN - CU-DHP EN - CU-DHP EN - CU-DHP EN - CU-DHP EN - CU-DHP EN - CU-DHP Pressure class PN0 PN0 PN0 PN0 PN0 PN0
TTV valve KPa mbar mmws 0² 0³ 0 0 0 0² 0³ 0 0² POSITIONS KVs m³/h 0.00 0.00 0.0 0.0 0.0 0.0 0.0 0.0.00 0.00 0 0. 0 0.0 0.0 0.0 0.0 0.0 0.0 0. 0. 0. 0. 0. 0. 0 Q m³/h Diagram. Valve settings for thermal actuators.
Pressure drop in water circuit, cooling has a factory-preset total pressure drop of kpa across the valve hoses and battery, at a nominal flow calculated on the basis of t (water in out ) K. (see table ). System length [mm] 00 00 00 000 00 00 Nominal flow [l/s] 0.0 0.0 0.0 0.0 0.0 0.0 Table., nominal flow. [l/s] Water Flödeflow 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 0,0 Ø 000 00 00 Ø0 00 00 00 0 0.0 0,0 0.0 0,0 0.0 0,0,.., 0 0 Minimum allowed flow of 0.0 l/s (Ø ) and 0.0 l/s (Ø0) Pressure Tryckfall Drop p w [kpa] Diagram. Pressure drop in the battery's cooling circuit. Example Cooling: 000, which provides an output of W. t w = K q w = P w / (c pw t w ) q w = / (00 x ) = 0.0 l/s The pressure drop in the water circuit in diagram is read off as Δp w =. kpa. Definitions: q w = 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] 0
Pressure drop in water circuit, heating has a factory-preset total pressure drop of kpa across the valve and battery, at a nominal flow calculated on the basis of t (water in out) 0 K. (see table ). System length [mm] 00 00 00 000 00 00 Nominal flow [l/s] 0.0 0.0 0.0 0.0 0.0 0.0 Table., nominal flow. [l/s] Water Flödeflow 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 0,0 0.0 0,0 0.0 0,0 0.0 0,0 Ø 000 00 00 Ø0 00 00 00 0. 0, 0, 0. 0. 0, 0. 0, 0. 0, 0. 0,,. 0 Minimum allowed flow of 0.0 l/s (Ø ) and 0.0 l/s (Ø0) Pressure Tryckfall Drop p w [kpa] Diagram. Pressure drop in the battery's heating circuit 0 [l/s] Water flow 0.0 0,0 0.0 0,0 0.0 0,0 0.0 0,0 Heating Cooling 0.0 0,0 0.0 0,0 0 0. 0,.,., Pressure Drop p w [kpa] Diagram. Pressure drop in the flexible pipes. Heating at 0 C, cooling at C.
Dimensions 0 0 0 0 0 0 Underside of board Underside of board Underside of board 0 0 0 0 0 0 00 0 0 Unit length 00 mm Unit length 000 mm 0 0 0 0 0 0 L- L- 0 0 00 0 L-0 L+ L- ø00 0 0 0 0 L-0 L+ ø0 ø00 0 L-0 L+ Dimensions of pipe bracket (accessory). Figure. standard, dimensions.
Dimensions 0 0 Underside of board 0 0 Underside of board 0 0 Underside of board 0 00 0 0 Unit length 00 mm Unit length 000 mm 0 00 0 0 L- 0 0 0 0 L- 00 00 ø00 0 0 L-0 L+ ø0 L- L-0 L+ Figure. low, system dimensions. ø00 L-0 L+
Distribution diagrams, - 00 The measurements were conducted with cooled supply air ( t room air supply air C) and cooling in the water circuit ( t room mean water temperature 0 C). Measurements were made according to the V method. All heat supplied through the walls. Isos 0.0 m/s ca 00-00 mm ca 00-00 mm ca 000-00 mm ca 000-00 mm ca 00-000 mm ca 000-00 mm l/s l/s l/s l/s l/s l/s 0 00 mm 00 mm 00 mm 00 Pa 0 Pa 00 mm 00 mm 00 mm ca 00-00 mm ca 00-00 mm ca 00-00 mm ca 00-00 mm ca 00-00 mm ca 00-00 mm l/s l/s l/s l/s l/s l/s 00 mm 00 mm 00 mm 00 mm 00 mm 00 mm 00 Pa 0 Pa Figure. 00 distribution diagrams, different air and flow settings.
Distribution diagrams, 00 The measurements were conducted with cooled supply air ( t room air supply air C) and cooling in the water circuit ( t room mean water temperature 0 C). Measurements were made according to the V method. All heat supplied through the walls. Isos 0.0 m/s ca 00-00 mm ca 00-00 mm ca 00-00 mm ca 00-000 mm ca 00-00 mm ca 00-000 mm l/s l/s 0 l/s l/s l/s l/s 00 mm 00 mm 00 mm 00 mm 00 mm 00 mm 00 Pa 0 Pa 0 ca 00-00 mm ca 00-00 mm ca 00-000 mm l/s l/s l/s 00 mm 00 mm 00 mm 00 Pa 00 mm Figure. 00 distribution diagrams, different air and flow settings.
0 Specification System: Length, [mm]: 00, 00, 00, 000, 00, 00 Duct dimension, [mm]: Ø00, Ø0, Ø00 Height, [mm]: Standard 0 - Ø00, 00 - Ø0, 0 - Ø00 Low model 00 - Ø00, 0 - Ø0, 00 - Ø00 Air quantity, [l/s]: - 0 l/s Nozzle pressure, [Pa]: 00-0 Pa Plus features: Regula Secura Floor connection Only heating or cooling Indicate connection dimension System accessories: T pipe --: Indicate type and quantity T pipe --: Indicate type and quantity Termination pack with air bleed: Heating and cooling Heating or cooling Nipple Ø00, Ø0, Ø00 Indicate diameter and quantity Windowsill grill/straight flow: Indicate system size Windowsill grill/angled flow: Indicate system size Windowsill grill Galea with arched ribs: Indicate system size Control equipment: Regula Combi, Thermostat cable Transformer F 0 VA (Max. systems) Transformer F VA (Max. systems) Order code Product 000 00 0 0 0 Type: Product length: 00, 00, 00, 000, 00, 00 Height: Standard, Low Air connection: 00, 0, 00 Static nozzle pressure (Pa): Air volume (l/s): Programme text from Lindab Qty Product: --000-00-0 0 Air quantity: 0 l/s Air pressure: 0 Pa Plus features: Regula Secura condensation guard: Accessories: Regula Combi: 0 Thermostat cable: 0 Extension cables: 0 Pipe bracket: 0 Termination pack, incl. air bleed: 0 Galea grill 000 white: 0