Hydrocomponents & Technologies Inc.

Motors


HCTI motors

HCTI Motors By Leeson 50/60 Hz Operation 56-C Frame

HCTI motors by Leeson

    Features

  • Quality components
  • Reliable
  • Stocked – Not Special Ordered
  • Compact in Size
  • Wider Range of Acceptable Voltage Than Stock Motors to Accommodate “Dirty Power”
  • C Face with a Rigid Welded Base
  • Motors 10 HP and smaller are lubricated at the factory to operate for long periods under normal service conditions without re-lubrication. Excessive or too frequent lubrication may actually damage the motor
Single Phase Motor 50/60 Hz
115-230 Volt, Open Drip-Proof, Frame 56-C with Rigid base
Part # HP RPM Volts Frequency NEMA frame Price
115463 3/4 1450/1725 115/230 50/60Hz 56-C $345.00
115445 1 1450/1725 115/230 50/60Hz 56-C $387.00
Three Phase Motor 50/60 Hz
208-230/460 Volt, Open Drip-Proof, Frame 56-C with Rigid Base
Part # HP RPM Volts Frequency NEMA frame Price
115444 1.5 1450/1725 208-230/460 50/60Hz 56-C $223.50
115464 2 1450/1725 208-230/460 50/60Hz 56-C $275.55
Typical re-lubrication intervals
Hours of service per year re-lubrication interval
5000 5 Years
Continuous Normal 2 Years
*These motors do not derate at 50Hz

Baldor motors

Nema 65-C with Resilient Base

Baldor motor

    Features

  • Sleeve or ball bearings.
  • Completely interchangeable with OEM Units.
  • Designed for replacements on many OEM carbonater pumps, sump pumps, and hot water circulators.

    Applications

  • Pumps
  • Fans
  • Conveyors
  • Machine tools
  • Gear reducers
Products
Part # HP RPM Volts Frequency NEMA frame Weight Price
CL1310 1 1725 115/230 60Hz 56-C 32 $332.00

GE/Marathon motors

Nema 48YZ with Resilient Base

GE motor

    Features

  • Sleeve or ball bearings.
  • Completely interchangeable with OEM Units.
  • Designed for replacements on many OEM carbonater pumps, sump pumps, and hot water circulators.
GE motor diagram
GE H683, H684 & H714
Part # Model # HP RPM Volts Frequency NEMA frame Weight C dimmension Price
H683 5KH33GNA444X 1/3 1725/1425 100-120/200-240 50 or 60Hz 48Y 14 7.9 in. $160.00
H684 5KH36MNA445X 1/2 1725/1425 100-120/200-240 50 or 60Hz 48Y 17 8.8 in. $160.00
H714 5KH37PNA479X 3/4 1725 115/230 60Hz 48Y 19 9.1 in. $190.00

Leeson motors

Rigid Base Motors for 50 or 60 Hz Operation

Leeson motor

Features

Motors 10 HP and smaller are lubricated at the factory to operate for long periods under normal service conditions without re-lubrication. Excessive or too frequent lubrication may actually damage the motor

Typical re-lubrication intervals
Hours of service per year re-lubrication interval
5000 5 Years
Continuous Normal 2 Years
Single phase 60Hz
Part # HP RPM Volts Frequency NEMA frame Price
101650 3/4 1725 115/208-230 60Hz 56-C $160.00
113930 1 1725 115/208-230 60Hz 56-C $320.00
113932 1.5 1725 115/208-230 60Hz 56-C $342.00
113281 2 1725 115/208-230 60Hz 56-C $420.00
120992 2 1725 115/208-230 60Hz 145-TC $367.00
Three phase 60Hz
Part # HP RPM Volts Frequency NEMA frame Price
100602 3/4 1725 208/230-460 60Hz 56-C $222.00
110901 1 1725 208/230-460 60Hz 56-C $254.00
110902 1.5 1725 208/230-460 60Hz 56-C $268.00
120275 2 1725 208/230-460 60Hz 56-C $287.00
Single phase 50Hz
Part # HP RPM Volts Frequency NEMA frame Price
110396 3/4 1425 110/200 50Hz 56-C $357.00
110397 1 1425 110/200 50Hz 56-C $392.00
110398 1.5 1425 110/200 50Hz 56-C $437.00
131553 2 1425 110/200 50Hz 56-C $531.00
Three phase 50Hz
Part # HP RPM Volts Frequency NEMA frame Price
114307 3/4 1425 220/380/440 50Hz 56-C $332.00
114888 1 1425 220/380/440 50Hz 56-C $334.00
Three phase 60Hz suitable for 50Hz
Part # HP RPM Volts Frequency NEMA frame Price
121004 1.5 1425 208-230/460 50Hz 145-TC $282.00
121005 2 1425 208-230/460 50Hz 145-TC $383.00
Leeson diagram NEMA dimensions

Most failures result from inappropriate application. Pay careful attention to the application requirements before choosing a motor for replacement of a failed one or for a new design application. Not choosing the correct motor type and horsepower can cause repeated motor failure and equipment downtime. Obviously, you don't want to specify a motor too small for the application, thus resulting in electrical stresses that cause premature motor failure. But neither should you specify a motor too powerful -- either because of its power or its inherent design characteristics. It can also have serious effects. For example, a motor with high locked-rotor and breakdown torques can damage the equipment it drives. Also, running a motor at less than full rated load is inefficient, costing you money for power wasted.