HRX-OM-W032 For a facility having a small installation area (that can not vent the air naturally): Make a forced air exhaust vent on a wall at a high level and an air inlet on a wall at a low level. 3.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Size: 1/8, Thread: M Thread, Rc(PT), Port Size: 1/4, Accessory: Bracket, Option 1: None, Option 2: C [Bowl Guard (Size 2000 Only)]
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
Facility having a small installation area (that can not vent the air naturally) Make a forced air exhaust vent on a wall at a high level and an air vent on a wall at a low level.
P = 43 PA 23 A A B B 14 12 A PA PA L1 L2 L2 L1 B B B 14 12 A A A A B 14 A A PA B B (2n 1/8) 4n-1/4, 3/8 2, 4 port PA L-side R-side L-side R-side D-side D-side 89 3 89 16 141 (Single) 141 (Single) 55 44 186 (Double) 186 (Double) 196 (3 position) 196 (3 position) 77.5 Bottom ported M12 connector L: Dimensions n: Stations 141.5 L n 1 Formula 2 3 4 5 6 7 8 9 10 121 5 1 12 14 PA PB 107 L1 = 43n
Rc1/4 Rc3/8 Bottom Note) When equipped with control unit, 1 or 2 stations are used for mounting. 6 Series VQ7-6 DIN Connector Type VV71-100 80 2n-Rc1/4, 3/8 100 80 9 37 9 23 14 U side 15 R4.5 Manual override Indicator light R4.5 53.5 P=43 9 9 53.5 P=43 20 9 23 38 B B B B B B B B B SMC SMC SMC A PA PA PA PA A A A A B A L1 L2 L2 L1 B A B SMC A B A 4n-Rc1/4, 3/8 (ports A, B) PA L side R side
HRS 100/150 Applicable model Dimension [mm] A B C HRSH250/300-A--A 916 536 1838 HRSH100/150/200-A--A 830 401 1538 HRSH100/150/200/250-W--A 570 1353 HRSH 090 HRSH HRSH HRSE HRZ HRZD HRW C HECR HEC 118 HEB A B HED HEA Option symbol With Earth Leakage Breaker B IDH HRSH 20 B With earth leakage breaker A leakage breaker is built in to automatically stop the supply power when it has short-circuit
HRS 100/150 HRS 100/150 Applicable model Dimension [mm] A B C HRS100/150-A-20/40-A 830 302 1552 HRS100/150-W-20/40-A 570 401 1353 C HRSH 090 HRSH 118 HRSE A B Option symbol With Earth Leakage Breaker B HRZ HRZD HRS 20 B With earth leakage breaker HRW A leakage breaker is built in to automatically stop the supply power when it has short-circuit, over current or electrical leakage.
(per unit) Applicable model A B C D HRSE012-AHRSE018-AHRSE024-A240 (335) 505 (540) HRW HRS-TK003 HECR HRSE012-A--T HRSE018-A--T HRSE024-A--T 240 (335) 555 (590) HEC HEB HED HEA IDH Anchor bolt (M8) D C (Prepared by user) Anti-quake bracket Material: Zinc steel plate Mounting view A B w Bypass Piping Set Note) To be mounted by user.
Applicable model Dimension in [mm] A B C HRS100/150-A-20/40-A 32.7 [830] 11.9 [302] 61.1 [1552] HRS100/150-W-20/40-A 22.4 [570] 15.8 [401] 53.5 [1353] C 118 A B Option symbol With Earth Leakage Breaker B HRS 20 B With earth leakage breaker A leakage breaker is built in to automatically stop the supply power when it has short-circuit, over current or electrical leakage.
x V x C x iT it m x C x (T0 Tt) it Q = = 1 x 150 x 4.186 x 103 x 10 900 = = 6977 [J/s] 7.0 [kW] m x C x (T0 Tt) it x 860 x V x 60 x C x iT it x 860 Q = = Cooling capacity = Considering a safety factor of 20%, 7.0 [kW] x 1.2 = 1 x 150 x 60 x 1.0 x 103 x 10 15 x 860 8.4 [kW] = Q x t: Heat capacity [kJ] Thermo-chiller Water bath 6977 [W] = 7.0 [kW] 20C Cooling capacity = Considering a safety
HRZ x V x C x iT it m x C x (T0 Tt) it Q = = HRZD 1 x 150 x 4.186 x 103 x 10 900 = = 6977 [J/s] 7.0 [kW] m x C x (T0 Tt) it x 860 x V x 60 x C x iT it x 860 HRW Q = = Cooling capacity = Considering a safety factor of 20%, 7.0 [kW] x 1.2 = HECR 1 x 150 x 60 x 1.0 x 103 x 10 15 x 860 8.4 [kW] = HEC Q x t: Heat capacity [kJ] Thermo-chiller Water bath 6977 [W] = 7.0 [kW] 20C HEB Cooling
Table 3.8-2 RTU mode message frame a)Start b)Slave Address c)Function d)Data e) Checksum (CRC) f)End T1-T2-T3-T4 XX XX XX XX XX XX T1-T2-T3-T4 a) Start In Modbus RTU mode, message frames are separated by a silent interval (non-communication time).
Table 3.8-2 RTU mode message frame a)Start b)Slave Address c)Function d)Data e) Checksum (CRC) f)End T1-T2-T3-T4 XX XX XX XX XX XX T1-T2-T3-T4 a) Start In Modbus RTU mode, message frames are separated by a silent interval (non-communication time).
Table 3.8-2 RTU mode message frame Address c)Function d)Data e)Checksum a)Start b)Device (CRC) f)End T1-T2-T3-T4 XX XX XX XX XX XX T1-T2-T3-T4 a) Start In Modbus RTU mode, message frames are separated by a silent interval (noncommunication time).