3 Engineering

LXM32

3.1Energy balance

To be able to estimate the effect of an interconnection of drives via a common DC bus, create an energy balance of the individual drives over a movement cycle. A movement cycle typically consists of the fol- lowing phases: acceleration, continuous movement and deceleration.

The energy generated during deceleration can be used by other drives connected via a common DC bus. Excess energy can be absorbed by the braking resistors.

The assessment of the energy balances of the individual drives per movement cycle and of the cyclic sequence of the movement cycles allows you to draw a conclusion regarding the efficiency of a common DC bus.

3.1.1Energy balance basics

The energy balance is influenced by the following factors:

Energy absorption of capacitors Evar in the drive

Electrical losses of the drive system Eel

Mechanical losses of the facility and the drive system Emech

Braking resistor EB

Energy absorption of the capaci- The higher the mains voltage, the lower the energy absorption of the tors Evar capacitors Evar. In your calculation, use the values for the highest

mains voltage that is used in your application, see chapter "2.3 Braking resistor".

The energy absorption of the capacitors Evar is the square difference between the voltage prior to the start of the deceleration and the switch-on voltage of the braking resistor.

Electrical losses Eel The electrical losses Eel of the drive system can be estimated on the basis of the peak power of the drive. The maximum power dissipation is approximately 10% of the peak power at a typical efficiency of 90%. If the current during deceleration is lower, the power dissipation is reduced accordingly.

Mechanical losses Emech The mechanical losses result from friction during operation of the sys- tem. Mechanical losses are negligible if the time required by the sys- tem to coast to a stop without a driving force is considerably longer than the time required to decelerate the system. The mechanical los- ses can be calculated from the load torque and the velocity from which the motor is to stop.

Braking resistor EB Two characteristic values determine the energy absorption of a brak- ing resistor:

The continuous power PPR is the amount of energy that can be

 

continuously absorbed without overloading the braking resistor.

MNA01M001EN,V1.01, 08.2014

The maximum energy ECR limits the maximum short-term power

 

that can be absorbed.

22

Common DC bus

Page 22
Image 22
Schneider Electric MNA01M001EN manual Energy balance basics

MNA01M001EN specifications

The Schneider Electric MNA01M001EN is a highly advanced solution designed to optimize energy management and enhance operational efficiency in various applications. As a crucial component in Schneider Electric's portfolio of energy management systems, the MNA01M001EN stands out due to its innovative features and robust technologies.

One of the main features of the MNA01M001EN is its seamless integration capabilities. The device supports interfaces such as Modbus, which allows it to connect to a variety of energy monitoring devices and systems. This interoperability ensures that users can easily connect their existing infrastructure without needing significant alterations, streamlining the energy monitoring process.

Another notable characteristic of the MNA01M001EN is its real-time monitoring capabilities. The device provides instant access to critical data, which enables users to make informed decisions regarding energy consumption. By continuously tracking energy usage, the MNA01M001EN facilitates timely interventions that can lead to substantial energy savings and improved operational performance.

In terms of technology, the MNA01M001EN employs advanced analytics to interpret energy data effectively. This feature empowers businesses to identify patterns in energy consumption, recognize inefficiencies, and make strategic adjustments. The use of predictive analytics also enables proactive maintenance strategies, minimizing potential downtime and optimizing resource allocation.

The MNA01M001EN is designed with user-friendliness in mind. Its intuitive interface simplifies navigation, making it accessible to a wide range of users, from energy managers to facility operators. Moreover, the device is equipped with customizable dashboards that allow users to visualize important metrics in ways that suit their specific needs and preferences.

In addition, the MNA01M001EN is built with sustainability as a core principle. By promoting energy efficiency, the device not only helps organizations reduce their carbon footprint but also leads to significant cost savings in energy bills. As organizations continue to prioritize sustainability, products like the MNA01M001EN play an essential role in driving those efforts forward.

Furthermore, its compact design allows for easy installation in various environments, making it a versatile choice for different types of facilities, whether industrial, commercial, or residential. The robust build quality ensures durability, allowing the device to withstand demanding conditions.

In summary, the Schneider Electric MNA01M001EN is an essential tool in modern energy management. With its integration capabilities, real-time monitoring, advanced analytics, user-friendly design, and commitment to sustainability, it represents a powerful solution for organizations looking to optimize their energy usage and enhance their operational efficiency.