EK Power DrivesTM is our new trademark for custom designed electrical motor drives. We have designed high-efficient motor drives with cutting edge technologies since 2003. Our proven custom drive solutions are used worldwide and are appreciated for their high quality and reliability.
We have designed control systems for all types of electric motors. This includes permanent magnet (PM) motors, brushless motors, stepper motors, and both AC induction- and DC-motors.
Our list of designs includes AC mains single- or three phase connected
systems to battery driven applications. Typical power levels are up to 50 kW or
By combining latest advancements in power semiconductor technology (SiC and GaN), PCB design and thermal dissipation, we can provide high power drives with minimum footprint. Our designs offer advanced algorithms and hardware protections that enable a highly efficient regeneration of power, in battery systems protecting the batteries from current peaks and overvoltage’s.
Our strength is to design robust products for harsh environments. High
quality and reliability requirements are our everyday lives. We always look for
the best overall system solution. In our design we focus on high efficiency to
reduce losses and maximize battery life if connected to such systems. Size and
weight also play an important role in having a more compact solution that can
better fit into the system mechanics.
In our 300 sqm electronics lab we have breaking benches to measure motor
performance, all with the aim of securing the product quality and reliability.
Our motor drives typically have the following functions:
Typical hardware functions
Single- or three phase PFC (1P Standard, 1P Semi-bridgeless, Bi-directional 3P Two level or 3P Vienna)
Two level 3P motor inverter is standard, but three level to be implemented in the future.
Regenerative braking and/or brake resistor
HW mains fault detection
2 channel STO (Safe Torque Off) in hardware
Hardware I/O fault and fault warning signals
Transformer isolated Ethernet or EtherCat (Safety)
Isolated CAN (Safety)
Encoder HW interfaces (HTL/TTL Incremental and Hall-sensor)
Back-up/log memory (FRAM and/or QSPI PSRAM
Micro SD-card (“Black box” memory and possible SW update channel)
PWM FAN control (temperature controlled from SW) of up to two fans with tacho feedbacks.
Internal/external 24V power supply with safety isolation
Typical software functions
Speed control with adaptive acceleration.
Automatic field weakening for increased top-speed of motors.
High speed logging of motor-control data.
Automatic on-target calculation of FOC-control parameters using the motor (electrical/mechanical) parameters.
Automatic measurement of motor winding-temperature with or without use of temperature sensors.
SPWM or SVPWM-mode available for open-loop control/testing of motors and drive.
Measurement (RMS) and monitoring of VAC-current.
Continuous measuring of the consumed (accumulated) energy to maximize performance while avoiding tripping the fuse.
Control/feedback using SPI and SDO/PDO.
Re-flash of SW using bootloader over SPI.
Communication over Ethernet, EtherCAT, CANopen according to CiA 402.
Encoders (HTL/TTL Incremental and Hall-sensor)
Automatic adjustment of fan-speed depending on device temperature. To maximize cooling performance without unnecessary audible noise. Fan failure detection from hardware.
Typical safety standards
EN 60745 / EN 62841
ISO 13849 Functional safety / IEC 61508
Typical communication protocols
Serial Peripheral Interface (SPI) is a communication protocol used for high-speed serial communication between one master controller and one or more slave devices. Its configuration allows for multi-axis architectures, which combined with its easy implementation results in faster system design while still maintaining performance and very low latency. Its application for motion control servo systems leads to getting the best of both centralized and distributed multi-axis architectures.
Ethernet for Control of Automation Technology, often referred as
EtherCAT is a standardized Ethernet-based fieldbus system developed by Beckhoff
Automation. EtherCAT use the fastest industrial Ethernet Technology and
synchronize with nanosecond accuracy. This reduces the wait times between
process steps, increases application efficiency, and provide the best fit for
distributed control in high performance applications.
CANopen is a CAN-based communication system. It comprises higher-layer
protocols and profile specifications. CANopen has been developed as a
standardized embedded network with highly flexible configuration capabilities.
It was designed originally for motion-oriented machine control systems. Today it
is used in various application fields, such as medical equipment, off-road
vehicles, maritime electronics, railway applications, or building automation.
Why a custom design solution?
There are a few main reasons for our customers to go for a custom designed
motor drive. They need a drive that have:
a specific shape or form factor.
a specific functionality not
available in off-the-shelf drives.
a drive optimized for their
reduce costs for higher production
The benefit is also that we on a custom design drive solution can
incorporate your functional needs or e.g. custom designed power supply to
support external functions.
If your product requires a high quality and reliable custom designed
electrical motor drive, do not hesitate to contact us.
Faced with the choice of a design partner, ABB evaluated a number of possible suppliers, eventually settling on EK Power Solutions because of their expertise throughout the process chain, from design to verification of finished prototypes. The project has faced many challenges, and together with our own design engineers, EK Power Solutions has been able to solve the issues that have come up. They have certainly lived up to our expectations, both in terms of technical expertise and understanding of the product, not to mention responsiveness.
Jesper Bergsjö, R&D Manager Control System Development, Robotics ABB