E-mail: wisdomlongkeji@163.com
Cellphone: +0086-13534205279
SIMILAR PRODUCTS
YASKAWA SGMPH series servo motors SGMPH-15AAA6CD-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-04DAA61D-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-01AAA6CD-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-02D1A61D-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-08DAA61D-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-01AAA61D-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-01A1A6CD-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-04DAA6CD-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-08D1A61D-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
YASKAWA SGMPH series servo motors SGMPH-02D1A6CD-OY
The SGMPH servomotor series has a medium inertia design with a flat profile providing the highest torque-per-length ratio available. These servomotors are well suited for applications requiring optimized load matching. There are five frame sizes providing up to 2,027 oz-in of peak torque. 100 and 20
Alternating circuits (resistive). Schematic representation of a sinusoidal voltage of magnitude E applied on a circuit with a resistive load R. The schematics shows the resultant current i in phase with the voltage v. It also shows the phasor representation of the voltage and current. of the angle (or power factor) depends on how capacitive or inductive the load is. In a purely capacitive circuit, the current will lead the voltage by 90◦
, while in a purely inductive one, the current will lag the voltage by 90◦ (see Fig. 1.9).
A circuit that has capacitive or inductive characteristics is referred to as being a reactive circuit. In such a circuit, the following parameters are defined:
S: The apparent power → S = E × I, given in units of volt-amperes or VA.
P: The active power → P = E × I × cos ϕ, where ϕ is the power angle of the circuit. P is given in units of watts.
Q: The reactive power → Q = E × I × sin ϕ, given in units of volt-amperes-reactive or VAR.