Rated Flow Range: 2 (2.5 to 100 L/min), Output Specifications: B (OUT 1: PNP; OUT 2: PNP; Integrated Display Type), Port Size: 6 (3/4; Applicable to LFE2), Thread: N (NPT), Option: Lead Wire w/M12 Connector; L/min Unit Specification, Insulation Type: None, Piping Port is Connected to Negative ground of Power Supply), Piping Connection: X8 (Stainless Steel 304)
Piping connections are C37 brass as standard, while the -X8 option offers 304 stainless steel. LFE is IP65 rated, and CE and RoHS compliant. Flow ranges (lpm): 0.5-20, 2.5-100, 5-200; Port sizes (Rc, NPT, G): 3/8, 1/2, 3/4, 1, (flow range dependent); Temperature rating: 0-85°C; Output options: NPN/PNP, 1-5V, 4-20mA; Accuracy: ±4% F.S. ; Repeatability: ±2% F.S.
Piping connections come in C37 brass as standard, while the -X8 option offers 304 stainless steel. LFE is IP65 rated, and CE and RoHS compliant. Flow ranges (lpm): 0.5-20, 2.5-100, 5-200; Port Sizes (Rc, NPT, G): 3/8, 1/2, 3/4, 1 (flow range dependent); Temperature rating: 0-85°C; Output options: 1-5v, 4-20mA; Accuracy: ±4% F.S.; Repeatability: ±2% F.S.
The X8 option is a dust-proof and water-jet-proof specification equivalent to IP67. This spec is achieved with the addition of several unique features above the standard LEY. The motor is sealed within an aluminum cover, fitted with M-type metal cable connectors. The rod passes through a scraper and employs a lubrication retainer to prevent oil film washout.
Piping connections are C37 brass as standard, while the -X8 option offers 304 stainless steel. LFE is IP65 rated, and CE and RoHS compliant. Flow ranges (lpm): 0.5-20, 2.5-100, 5-200; Port sizes (Rc, NPT, G): 3/8, 1/2, 3/4, 1, (flow range dependent); Temperature rating: 0-85°C; Output options: NPN/PNP, 1-5V, 4-20mA; Accuracy: ±4% F.S. ; Repeatability: ±2% F.S.
Piping connections come in C37 brass as standard, while the -X8 option offers 304 stainless steel. LFE is IP65 rated, and CE and RoHS compliant. Flow ranges (lpm): 0.5-20, 2.5-100, 5-200; Port Sizes (Rc, NPT, G): 3/8, 1/2, 3/4, 1 (flow range dependent); Temperature rating: 0-85°C; Output options: 1-5v, 4-20mA; Accuracy: ±4% F.S.; Repeatability: ±2% F.S.
The X8 option is a dust-proof and water-jet-proof specification equivalent to IP67. This spec is achieved with the addition of several unique features above the standard LEY. The motor is sealed within an aluminum cover, fitted with M-type metal cable connectors. The rod passes through a scraper and employs a lubrication retainer to prevent oil film washout.
The X8 option is a dust-proof and water-jet-proof specification equivalent to IP67. This spec is achieved with the addition of several unique features above the standard LEY. The motor is sealed within an aluminum cover, fitted with M-type metal cable connectors. The rod passes through a scraper and employs a lubrication retainer to prevent oil film washout.
The X8 option is a dust-proof and water-jet-proof specification equivalent to IP67. This spec is achieved with the addition of several unique features above the standard LEY. The motor is sealed within an aluminum cover, fitted with M-type metal cable connectors. The rod passes through a scraper and employs a lubrication retainer to prevent oil film washout.
Table of Contents Calculation of Load Factor for Static Load m1: Mass m1 m1 max (from q of graph MY3A m1) = 10.7 (kg) Load factor 1 = m1 m1 max = 0.8 10.7 = 0.08 X M1: Moment m1 M1 max (from w of graph MY3A M1) = 4 (Nm) M1 = m1 x g x X = 0.8 x 9.8 x 5 x 10-3 = 0.04 (Nm) M1 Load factor 2 = M1 M1 max = 0.04 4 = 0.01 M2: Moment Y M2 max (from e of graph MY3A M2) = 0.8 (Nm) m1 M3 = m1 x g x Y = 0.8 x 9.8
Calculation of Load Factor for Static Load m1: Mass m1 m1 max (from (1) of graph MY1B/m1) = 27 (kg) Load factor 1 = m1/m1 max = 2/27 = 0.07 X M1: Moment m1 M1 max (from (2) of graph MY1B/M1) = 13 (Nm) M1 = m1 x g x X = 2 x 9.8 x 20 x 10 3 = 0.39 (Nm) M1 Load factor 2 = M1/M1 max = 0.39/13 = 0.03 M2: Moment Y M2 max (from (3) of graph MY1B/M2) = 1.6 (Nm) m1 M3 = m1 x g x Y = 2 x 9.8 x 30 x
Calculation of Load Factor for Static Load m1: Weight m1 m1max (from (1) of graph MY1B/m1) = 27 (kg) Load factor 1 = m1/m1max = 2/27 = 0.07 X M1: Moment m1 M1max (from (2) of graph MY1B/M1) = 13 (Nm) M1 = m1 x g x X = 2 x 9.8 x 20 x 10 3 = 0.39 (Nm) M1 Load factor 2 = M1/M1max = 0.39/13 = 0.03 M2: Moment Y M2max (from (3) of graph MY1B/M2) = 1.6 (Nm) m1 M3 = m1 x g x Y = 2 x 9.8 x 30 x 10
: Pitching y x M2: Rolling Static moment Ceiling mounting Horizontal mounting Wall mounting M1 M2 M2 M1 M2 M3 y X x Y y z X x Y X x Z m1 x g m2 x g m3 x g Vertical mounting Mounting orientation Horizontal Ceiling Wall Vertical m1 m2 m3 m4 Static load m M3 M1 m1 x g x X m2 x g x X m4 x g x Z Static moment M1 m1 x g x Y m2 x g x Y m3 x g x Z y z M2 z Y m3 x g x X m4 x g x Y M3 m4 x g g: Gravitational
X-axis Y-axis Z-axis Z 5 W 5 mm 10 mm 20 mm 0.8 kg 20 Y 10 3 Calculation of Load Factor for Static Load m1: Weight m1 m1 max (from q of graph MY3A m1) = 10.7 (kg) Load factor 1 = m1 m1 max = 0.8 10.7 = 0.08 X M1: Moment M1 max (from w of graph MY3A M1) = 4 (Nm) m1 M1 = m1 x g x X = 0.8 x 9.8 x 5 x 10-3 = 0.04 (Nm) M1 Load factor 2 = M1 M1 max = 0.04 4 = 0.01 M2: Moment Y M2 max (from
X LXS X-axis Y-axis Z-axis 5 Z W 4 kg 5 mm 10 mm 20 mm LC6m 20 LZm Y 10 LC3F2 3 Calculation of Load Factor for Static Load Xm m1: Mass D-m m1 m1 max (from 1 of graph m1) = 15.5 (kg) . E-MY Load factor a1 = m1 / m1 max = 4 / 15.5 = 0.26 X M1: Moment m1 M1 max (from 2 of graph M1) = 1.45 (NNm) .
Coordinates and Moments z M3: Yawing M1: Pitching y x M2: Rolling Static Moment Ceiling mounting Horizontal mounting Wall mounting CY3B CY3R M2 M1 M1 M2 M2 M3 CY1S Y y z y X x X x Y X x Z CY1L m1 x g m2 x g m3 x g CY1H Vertical mounting Mounting orientation Horizontal Ceiling Wall Vertical CY1F m1 m2 m3 m4 Static load m CYP m1 x g x X m2 x g x X m4 x g x Z Static moment M1 M3 M1 m3 x g x
Calculation of Load Factor for Static Load m1: Mass m1 m1 max (from q of graph MY3A m1) = 10.7 (kg) Load factor 1 = m1 m1 max = 0.8 10.7 = 0.08 X M1: Moment m1 M1 max (from w of graph MY3A M1) = 4 (Nm) M1 = m1 x g x X = 0.8 x 9.8 x 5 x 10-3 = 0.04 (Nm) M1 Load factor 2 = M1 M1 max = 0.04 4 = 0.01 M2: Moment Y M2 max (from e of graph MY3A M2) = 0.8 (Nm) m1 M3 = m1 x g x Y = 0.8 x 9.8