TCB-RB - TROX

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Installation · Assembly For the convection process to occur, it is essential that the air to be cooled can flow unhindered into the coil. The optimum condition for this is when distance Z – lower edge of ceiling slab to upper edge of beam is as large as possible (ideally Z W/2). It is also important to allow return air to enter the ceiling void. The return air path free area should be equivalent to the coil area and be split equally either side of the chilled beam. For example, if a perforated ceiling with a 50% free area is on the return air path, then the perforated area should be equal to twice the width x length of the coil. TROX TCB-RB chilled beams are provided with Ø10 mm holes, pre-punched within the top flange. The chilled beams can be suspended from the slab with threaded rod or suitable suspension wires. Beam Weight Beam Type Weight (kg/m) TCB-RB / RB-S 15 Airboot 5 TCB-RB mounting detail L 1 = 1200 mm up to 2999 mm L 1 = 3000 mm up to 4500 mm Coil Connection Detail Horizontal connection Vertical connection 4
Nomenclature · Example Nomenclature V WK in l/hr: Water volume flow rate, cooling Q WK in W: Water cooling capacity q WK in W/m: Specific cooling capacity per m W/m²: or per m² t WV in °C: Chilled water flow temperature t WR in °C: Chilled water return temperature t WM in °C: Chilled water mean temperature t R in °C: Maximum room air temperature t W in K: Temperature difference between water flow and return temperature t RW in K: Temperature difference between max. room air temperature and mean chilled water temperature V in m/s: Maximum time averaged air velocity measured approx. 1 m below passive chilled beam B in mm: Width of cooling coil H in mm: Passive beam stack height fo in %: Ceiling free area underneath the TCB-RB Z in mm: Return air gap above beam K Z/W Correction factor for Z /W ratio K fo Correction factor for airflow % free area p W in kPa: Water pressure drop Reference Values t WV = 16 °C Chilled water flow temperature t WR = 18 °C Chilled water return temperature t R = 27 °C Room air temperature t RW = 10 K Temperature difference between room air temperature and mean chilled water temperature Z/W = 0.5 Ratio of clear height against coil width Example Room size: 3 m x 6 m Room height: 2.8 m Suspended ceiling: 45% free area Ceiling void: 400 mm t R 24 °C t WV 14 °C t WR 17 °C t RW 8.5 K q WK 60 W/m² 60 x 3 x 6 = 1080 W Q WK The architect has specified a row of units maximum 6 m along the centre line of the room (2 x 3 m) Room sketch Diagrams I…III (see page 8) Coil width (B): 410 mm Unit height (H): 250 mm Unit length (L 1 ): 3000 mm Q = 550 W For installation behind a perforated ceiling 45%, correction factor K fo must be applied. K fo : 0.99 Q = 550 W x 0.99 = 544 W Diagrams IV and V At a differential between water flow and return temperature of 3 K, the water flow rate V W = 156 l/hr. Since the water flow rate is greater then the nominal water flow rate of 110 l/hr, a correction factor K W = 1.07 is applied to the calculated capacity Q = 544 W x 1.07 = 582 W Diagram VII For installation within a ceiling void, correction factor K Z/W must be applied. Z B = (400-250) = 0.36 410 K Z/W : 0.97 Q = 582 W x 0.97 = 565 W For the room as planned with 2 chilled beams units 3000 mm long, the available overall cooling capacity is: Q WK = 2 x 565 W = 1130 W Diagram VII Waterside pressure drop. p w = 0.7 x 3 m = 2.1 kPa Diagram VIII The air velocity 1 m below the chilled beam will be between 0.17 and 0.23 m/s. NOTE: If required cooling output cannot be achieved with a 1 row coil, repeat above steps with diagrams on page 9. 5
Page 1 and 2: T 2.4/8.1/B/1 Passive Chilled Beams
Page 3: Construction · Dimensions Construc
Page 7 and 8: Quick Selection 2 row coil Cooling
Page 9 and 10: Technical Data 2 row coil I II III
Page 11: Order details Specification text Ty

TCB-RB - TROX

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