[Main power supply]

 

In the following examples involving a general-purpose inverter, a large peak current flows on the main power supply side,

 

and may destroy the converter module. Where such situations are foreseen or the connected equipment must be highly reli-

 

able, install an AC reactor between the power supply and the inverter. Also, where influence of indirect lightning strike is pos-

 

sible, install a lightning conductor.

 

 

(A) The unbalance factor of the power supply is 3% or higher. (Note)

 

(B) The power supply capacity is at least 10 times greater than the inverter capacity (the power supply capacity is 500

 

kVA or more).

 

 

(C) Abrupt power supply changes are expected.

 

Installation of an

Examples:

 

(1) Several inverters are interconnected with a short bus.

 

AC reactor on the

(2) A thyristor converter and an inverter are interconnected with a short bus.

input side

(3) An installed phase advance capacitor opens and closes.

 

 

In cases (A), (B) and (C), it is recommended to install an AC reactor on the main power supply side.

 

Note: Example calculation with VRS = 205V, VST = 201V, VTR = 200V

 

 

VRS : R-S line voltage, VST : S-T line voltage, VTR : T-R line voltage

 

Max. line voltage (min.) – Mean line voltage

 

Unbalance factor of voltage = ——————————————————————— X 100

 

Mean line voltage

 

 

VRS – (VRS + VST + VTR )/3

205 – 202

 

= ————————————— X 100 = ————— X 100 = 1.5 (%)

 

(VRS + VST + VTR )/3

202

 

 

Using a private power

An inverter run by a private power generator may overheat the generator or suffer from a deformed output voltage waveform

of the generator. Generally, the generator capacity should be five times that of the inverter (kVA) in a PWM control system,

generator

or six times greater in a PAM control system.

 

 

 

 

 

 

Notes on Peripheral Equipment Selection

 

 

 

(1)Be sure to connect main power wires with R(L1), S(L2), and T(L3) (input) terminals and motor wires to U(T1), V(T2), and

Wiring connections

W(T3) terminals (output). (Incorrect connection will cause an immediate failure.)

 

 

 

(2)Be sure to provide a grounding connection with the ground terminal (

 

).

 

 

 

 

 

 

Electro-

When an electromagnetic contactor is installed between the inverter and the motor, do not perform on-off switching during

 

 

magnetic contactor

running operation.

 

 

 

 

 

 

Wiring

 

 

When used with standard applicable output motors (Hitachi standard three-phase squirrel-cage four-pole motors), the

 

 

L300P Series does not need a thermal relay for motor protection due to the internal electronic protective circuit. A thermal

between

 

 

relay, however, should be used:

inverter and

 

Thermal relay

during continuous running outside a range of 30 to 60 Hz.

motor

 

for motors exceeding the range of electronic thermal adjustment (rated current).

 

 

when several motors are driven by the same inverter; install a thermal relay for each motor.

 

 

 

 

 

 

The RC value of the thermal relay should be more than 1.1 times the rated current of the motor. Where the wiring length is

 

 

 

10 m or more, the thermal relay tends to turn off readily. In this case, provide an AC reactor on the output side or use a

 

 

 

current sensor.

 

 

 

Install a circuit breaker on the main power input side to protect inverter wiring and ensure personal safety. Choose an

Installing a circuit breaker

inverter-compatible circuit breaker. The conventional type may malfunction due to harmonics from the inverter. For more

 

 

 

information, consult the circuit breaker manufacturer.

 

 

 

The wiring distance between the inverter and the remote operator panel should be 20 meters or less. When this distance is

Wiring distance

 

exceeded, use CVD-E (current-voltage converter) or RCD-E (remote control device). Shielded cable should be used on the

 

 

 

wiring. Beware of voltage drops on main circuit wires. (A large voltage drop reduces torque.)

Earth leakage relay

If the earth leakage relay (or earth leakage breaker) is used, it should have a sensitivity level of 15 mA or more (per inverter).

 

 

 

 

 

 

Phase advance capacitor

Do not use a capacitor for power factor improvement between the inverter and the motor because the high-frequency

components of the inverter output may overheat or damage the capacitor

 

 

 

 

 

 

 

 

 

High-frequency Noise and Leakage Current

(1)High-frequency components are included in the input/output of the inverter main circuit, and they may cause interference in a transmitter, radio, or sensor if used near the inverter. The interference can be minimized by attaching noise filters (option) in the inverter circuitry.

(2)The switching action of an inverter causes an increase in leakage current. Be sure to ground the inverter and the motor.

Lifetime of Primary Parts

Because a smoothing capacitor deteriorates as it undergoes internal chemical reaction, it should normally be replaced every five years. Be aware, however, that its life expectancy is considerably shorter when the inverter is subjected to such adverse factors as high temperatures or heavy loads exceeding the rated current of the inverter.

The approximate lifetime of the capacitor is as shown in the figure at the right when it is used 12 hours daily (according to the “Instructions for Periodic Inspection of General-Purpose Inverter” (JEMA)).

Also, such moving parts (cooling fan) should be replaced. Maintenance inspection and parts replacement must be performed by only specified trained personnel.

)

 

 

 

(°C

 

 

 

temperature

50

 

 

40

 

 

30

 

 

Ambient

 

 

2.5

5

10

Capacitor lifetime (years)

 

Precaution for Correct Usage

Before use, be sure to read through the Instruction Manual to insure proper use of the inverter.

Note that the inverter requires electrical wiring; a trained specialist should carry out the wiring.

The inverter in this catalog is designed for general industrial applications. For special applications in fields such as aircraft, outer space, nuclear power, electrical power, transport vehicles, clinics, and underwater equipment, please consult with us in advance.

For application in a facility where human life is involved or serious losses may occur, make sure to provide safety devices to avoid a serious accident. The inverter is intended for use with a three-phase AC motor. For use with a load other than this, please consult with us.

Information in this brochure is subject to change without notice.

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Hitachi L300P manual High-frequency Noise and Leakage Current, Lifetime of Primary Parts
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L300P specifications

The Hitachi L300P is a versatile and highly efficient variable frequency drive (VFD) known for its robust performance and reliability across various industrial applications. This drive is part of Hitachi's renowned L-series, designed to provide precise motor control and energy savings, making it a popular choice among engineers and system integrators.

One of the standout features of the Hitachi L300P is its advanced vector control technology. This technology enables the drive to deliver superior torque control and operational efficiency, which is crucial for applications requiring high performance and accuracy. The L300P's sensorless vector control capability allows it to maintain optimal performance even in varying load conditions, ensuring that motors run smoothly and efficiently.

The L300P also boasts a wide input voltage range, accommodating different voltage requirements from 200V to 600V. This flexibility makes it suitable for diverse global applications without the need for voltage converters. Additionally, the drive supports a broad range of output frequencies, allowing for seamless integration with various motor types.

Another significant aspect of the L300P is its built-in PLC functionality. This feature enables users to implement simple control tasks directly within the drive, reducing the need for external controllers and minimizing installation space and complexity. With programmable logic capabilities, users can optimize their processes and add custom functionalities to meet specific operational requirements.

The L300P is equipped with comprehensive protection features, including overcurrent protection, overvoltage protection, and motor stall prevention. These safety mechanisms ensure that the drive and the connected motors remain protected under adverse operating conditions, enhancing system reliability and reducing maintenance costs.

In terms of user interface, the L300P includes an intuitive keypad that allows for easy parameter setting and monitoring. The display provides real-time information about operational status and performance metrics, enabling users to make informed decisions quickly.

Energy efficiency is another key characteristic of the L300P. By utilizing advanced control algorithms and motor management techniques, the drive significantly reduces energy consumption, making it an environmentally friendly choice for industries looking to lower their carbon footprint.

Overall, the Hitachi L300P combines advanced technology, robust performance, and user-friendly features, making it a pivotal component in modern industrial automation and control systems. With its flexibility and efficiency, it stands out as a reliable solution for a wide range of applications, from HVAC systems to conveyor control and beyond.
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