Product Description
Everest NET is a high power, highly-integrated, digital servo drive intended to be plugged or soldered to an application-specific daughter board. The drive features best-in-class energy efficiency thanks to its state of the art power stage, and can be easily configured with Ingenia's free-to-download software MotionLab 3.
Everest NET is enabled with EtherCAT and CANopen communications.
Main features:
- Ultra-small footprint
- Up to 80 VDC, 45 A continuous
- Up to 99% efficiency
- Up to 50 kHz current loop, 25 kHz servo loops
- 10 kHz ~ 100 kHz PWM frequency
- 16 bit ADC with VGA for current sensing
- Supports Halls, Quadrature encoder, SSI and BiSS-C
- Up to 4 simultaneous feedback sources
- Full voltage, current and temperature protections
Typical applications:
- Collaborative robot joints
- Robotic exoskeletons
- Wearable robots
- AGVs
- UAVs
- Industrial highly integrated servomotors
- Smart motors
- Battery-powered and e-Mobility
- Low inductance motors
Part numbering
Product | Ordering part number | Communications | Environment | Status | Image |
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Everest NET Pluggable servo drive with EtherCAT communications | EVE-NET-E | EtherCAT | Industrial | PRODUCTION | |
EVE-E-NET-E | EtherCAT | Extended | PRODUCTION | ||
Everest NET Pluggable servo drive with CANopen and Ethernet communication. | EVE-NET-C | CANopen / Ethernet | Industrial | PRODUCTION | |
EVE-E-NET-C | CANopen / Ethernet | Extended | PRODUCTION |
General Label Identification |
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For applications not requiring CANopen or EtherCAT, please see Everest CORE.
For applications requiring a ready-to-go product, please see Everest XCR.
Specifications
Electrical and Power Specifications
Part number → | Industrial (EVE-NET-E / EVE-NET-C) | Extended (EVE-E-NET-E / EVE-E-NET-C) |
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Minimum DC bus supply voltage | 8 VDC | |
Maximum DC bus supply voltage | 80 VDC (continuous) 85 VDC (peak 100 ms) Working at 80 V will require a stable power supply able to absorb any possible reinjection coming back from the driver. | 52 VDC (continuous) |
Recommended power supply voltage range | 12 VDC ~ 72 VDC This voltage range ensures a safety margin including power supply tolerances and regulation during acceleration and braking. | 12 VDC ~ 52 VDC |
Internal drive DC bus capacitance | 19 µF Note that EVE-NET uses ceramic capacitors. The capacitance value varies with DC bias and temperature. | |
Logic supply voltage | 4.9 VDC ~ 5.1 VDC Recommended voltage range is 5 V ± 2% Maximum absolute operating voltage range is 5 V ± 3% (4.85 V to 5.15 V) A minimum of 500 mA should be provided. Higher current may be needed depending on the feedbacks used. Rise time of the 5 V supply must be between 2 ms and 10 ms to guarantee a proper initialization. | |
Boot-up time | 15 s | |
Minimum shutdown time | 500 ms | |
Maximum continuous phase current | 45 A @ 60 ºC Typically, 45 A can be obtained working at 48 V, 20 kHz with an appropriate cooling to keep case temperature under 60 ºC. On higher temperatures an automatic current derating will be applied to protect the system. See Thermal and Power Specifications below. | |
Maximum peak phase current | 60 A @ 1 sec Notice that peak current could be limited by an automatic current derating algorithm. In order to get 60 A, case temperature should be kept below 35 ºC. | |
Maximum continuous switch-off rectified current |
Notice that maximum current is dependent on temperature and heatsink attached. At higher temperature, the lower the current. For more information about heatsink applied, see Thermal and Power Specifications below. A continuous use of disabled power stage as rectifier is not recommended for thermal limitations. | |
Maximum continuous output power | > 3 kW How the output power is calculated in an Ingenia drive. | |
Efficiency | Up to 99% | |
Maximum DC Bus voltage utilization | 99.73% @ 10 kHz 99.55% @ 20 kHz 99.04% @ 50 kHz 95.25% @ 100 kHz Note 1: these values assume a Sinusoidal commutation and no load connected. | |
Standby logic supply consumption | ≤ 2.2 W typ. See details and conditions in the section below. The measurement includes 150 mW corresponding to the Ethernet magnetics, not included in the Everest NET. |
Motion Control Specifications
Supported motor types |
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Power stage PWM frequency (configurable) | 10 kHz, 20 kHz (default), 50 kHz & 100 kHz | |||
Current sensing | 3 phase, shunt-based current sensing. 16 bit ADC resolution. Accuracy is ±2% full scale | |||
Current sense resolution (configurable) | Current gain is configurable in 4 ranges:
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Current sense ranges (configurable) | Current ranges for the 4 configurable current gains:
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Max. Current loop frequency (configurable) | 50 kHz Check the Power Stage & Control loops relationship section below. | |||
Max. servo loops frequency (position, velocity & commutation) (configurable) | 25 kHz Check the Power Stage & Control loops relationship section below. | |||
Feedbacks |
All feedback inputs are single-ended, 3.3 V logic levels. *Not all the existing absolute encoders are supported. Contact Ingenia for further information. | |||
Supported target sources | Network communication (EtherCAT / CANopen) | |||
Control modes |
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Inputs/Outputs and Protections
Inputs and outputs | 4x non-isolated single-ended digital inputs - 3.3 V logic level. Can be configured as:
4x non-isolated single-ended digital outputs - 3.3 V logic level, 3 mA max. sink / source current. Can be configured as:
2x ±3.3 V ,16-bit, differential analog input for load cells or torque sensors. Can be read by the Master to close a torque loop. | |||
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Shunt braking resistor output | Configurable over any of the digital outputs (see above). Enabling this function would require an external transistor or power driver. | |||
Motor brake output | Dedicated, PWM-capable, 3.3 V digital output for driving a mechanical brake. Turn-on and turn-off times are configurable. Enabling this function would require an external transistor or power driver. | |||
Safe Torque OFF inputs | 2x dedicated, non-isolated STO digital inputs (3.3 V and 5 V tolerant). | |||
Motor temperature input | 1x dedicated, 5 V, 12-bit, single-ended analog input for measuring motor temperature. NTC, PTC, RTD, linear voltage sensors , silicon-based sensors and thermal switches are supported. | |||
Protections |
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Communication for Operation
EtherCAT (EVE-NET-E / EVE-E-NET-E) | CANopen over EtherCAT (CoE) File over EtherCAT (FoE) Ethernet over EtherCAT (EoE) | |||
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CANopen / Ethernet (EVE-NET-C / EVE-E-NET-C) | CiA-301, CiA-303, CiA-305, CiA-306 and CiA-402 (4.0) compliant. 125 kbps to 1 Mbps (default). Non-isolated. Termination resistor not included. Note: Ethernet ports can be used to configure the drive. |
Environmental Conditions
Part number → | Industrial (EVE-NET-E / EVE-NET-C) | Extended (EVE-E-NET-E / EVE-E-NET-C) | ||
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Environmental test methods | IEC 60068-2 | MIL-STD-810G | ||
Case temperature (Operating) | -20 ºC to +85 ºC Check the Current Derating section below. | -40 ºC to +85 ºC Check the Current Derating section below. | ||
Case temperature (Non-Operating) | -40 ºC to +100 ºC | -50 ºC to +100 ºC | ||
Thermal Shock (Operating) | 25 ºC to 60 ºC in 25 min | -40 ºC to 70 ºC within 3 min | ||
Maximum Humidity (Operating) | up to 95%, non-condensing at 85 ºC | up to 95%, non-condensing at 85 ºC | ||
Maximum Humidity (Non-Operating) | up to 95%, non-condensing at 85 ºC | up to 95%, non-condensing at 85 ºC | ||
Altitude (Operating) | -400 m to 2000 m | -400 m to 10000 m | ||
Vibration (Operating) | 5 Hz to 500 Hz, 4-5 g | 20 Hz to 2000 Hz, 14.6 g | ||
Mechanical Shock (Operating) | ±15g Half-sine 11 msec | ±20g Half-sine 11 msec | ||
Mechanical Shock (Non-Operating) | ±15g Half-sine 11 msec | ±40g Half-sine 11 msec | ||
Pollution degree and installation environment | Pollution Degree 2 environment according to IEC 61800-5-1: Normally, only non-conductive pollution occurs. Occasionally, a temporary conductivity caused by condensation is to be expected when the Everest NET is off. | |||
Minimum index of protection of the installation | IP3X: Since Everest NET has accessible live electrical circuits, it should be installed on closed electrical operating areas with a minimum protection rating of IP3X and should be accessed by skilled or instructed persons. |
Reliability Specifications
Part number → | Industrial (EVE-NET-E / EVE-NET-C) | Extended (EVE-E-NET-E / EVE-E-NET-C) |
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MTBF | > 450.000 h Based on FIDES method for Standard Life Profile at 40 °C average. Other scenarios available on demand. | > 110.000 h Based on FIDES method for "Equipment (in avionics bay) mounted in a medium haul civil aircraft" at 40 ºC average. Other scenarios available on demand. |
Isolation between aluminum case (PE) and live circuits | Basic insulation according to IEC 61800-5-1. > 200 MΩ. Measured between PE (case) and GND_P and +SUP and phases. Note: The drive includes 2 nF EMC capacitance between the power supply negative (GND_P) and the enclosure (PE). |
Mechanical Specifications
Aluminum case | Yes (connectors side open). Minimum wall thickness > 0.75 mm. | |||
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Horizontal dimensions | 34.5 mm x 26 mm | |||
Height | 14.25 mm (including Mezzanine connector) 17 mm (including full length of the power pins) | |||
Weight | 23 gr |
Compliance
Part number → | Industrial (EVE-NET-E / EVE-NET-C) | Extended (EVE-E-NET-E / EVE-E-NET-C) | ||
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EC Directives | CE Marking
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Low Voltage Directive |
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Electromagnetic Compatibility (EMC) Standards |
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Product Safety Standard |
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Functional Safety Standard | Safe Torque Off (STO)
See Safety Manual - Safe Torque Off (STO) section for mandatory Integration Requirements. | |||
Environmental Test methods | IEC 60068-2:
| MIL-STD-810G:
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Thermal and Power Specifications
Standby power consumption
The following table shows the standby power consumption when the Everest power stage is disabled assuming 1 EtherCAT/Ethernet port is active and communicating at full speed, no feedbacks or I/Os are connected. At this point the power consumption comes from the 5 V supply input only. The table also shows the "active standby" dc bus power consumption when the power stage is enabled, motor current is set to 0 and housing temperature is kept at 50 ºC.
Power supply voltage | Standby 5 V logic supply consumption | Power stage DC bus consumption switching at 0 current | ||||
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EtherCAT (1 port active) | CANopen | 10 kHz | 20 kHz | 50 kHz | 100 kHz | |
12 V | 2.15 W (logic supply consumption does not depend on bus voltage) | TBD | 0.13 W | 0.19 W | 0.35 W | 0.62 W |
24 V | 0.17 W | 0.25 W | 0.48 W | 0.86 W | ||
48 V | 0.29 W | 0.46 W | 0.95 W | 1.77 W | ||
60 V | 0.37 W | 0.61 W | 1.29 W | 2.44 W | ||
72 V | 0.46 W | 0.78 W | 1.71 W | 3.25 W |
Thermal model
The Everest NET is designed to be mounted on a cooling plate or heatsink to achieve its maximum ratings. In order to calculate the heatsink requirements, the power dissipation can be estimated below.
In some low power applications, the Everest is NOT required to be mounted to any heatsink. In this case its thermal resistance from housing/case to ambient Rth(h-a) can be estimated between 8 K/W, to 12 K/W assuming 10 cm clearance to allow air convection at sea level. Typically 7 W can be dissipated without heatsink, refer to the graph below to know which current can be handled.
*Product shown differ from Everest NET.
Current derating
The following figure show the maximum motor phase current at different case temperatures and operating points. As can be seen lower temperature, bus voltage or PWM frequency allows higher current due to lower heat dissipation. For highest current, Everest can be configured at 10 kHz PWM frequency, however this may not be suitable for low inductance motors or acoustic noise sensitive applications. The graph expresses the achievable current including the derating algorithm that limits the current based operation conditions and the power stage temperature.
Notice that current is expressed in crest value for a 3 phase BLAC motor. For further clarifications and conversion to equivalent RMS values please refer to Disambiguation on current values and naming for Ingenia Drives.
To ensure a proper performance of Everest NET, the case temperature should be held always below 85 ºC (Tc-max = 85 ºC).
Heat dissipation and heatsink calculation
Following figure show the total power losses at different operating points. This includes logic supply which is an important contributor at low loads. As can be seen, lower PWM frequency and voltage leads to lower power losses.
Please, use the following procedure to determine the required heatsink:
- Based on the voltage & continuous (averaged) current required by your application and Current derating graph determine the Case temperature Tc. Remember that Case temperature must be always below 85 ºC (Tc < 85 ºC)
- For example: If the application requires 30 A @ 72 V (20 kHz) the Tc will be 85 ºC
- Based on the voltage & continuous current required by your application and Power losses graph determine the generated Power Losses PL to be dissipated.
- For example: If the application requires 30 A @ 72 V (20 kHz) the PL will be 19 W
- Determine the Thermal impedance of the used thermal sheet Rth(c-h)
- For example, a thermal sheet TGX-150-150-0.5-0, which has an estimated thermal impedance of Rth(c-h) = 0.2 K/W
Based on the ambient temperature and using the following formula determine the maximum thermal impedance to air of the required heatsink Rth(h-a)
- For example: If the application requires 30 A @ 72 V (20 kHz) working at Ta = 25 ºC and we use a thermal sheet with Rth(c-h) = 0.2 K/W the required thermal impedance of the heatsink will be Rth(h-a) = 3.35 K/W
Energy efficiency
The following graph shows the net energy efficiency including logic for various operation points assuming 50ºC case temperature and maximum output power. Very high efficiencies > 99% can be achieved at 10 kHz or 20 kHz PWM frequencies.
Power Stage & Control loops relationship
The power stage PWM frequency can be adjusted in 4 different frequencies. Each frequency has an associated rate for the control loops, as specified in the following table.
Power stage PWM frequency | Current loop frequency | Servo loops frequency (position, velocity, commutation & shunt) |
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10 kHz | 10 kHz | 10 kHz |
20 kHz | 20 kHz | 20 kHz |
50 kHz | 50 kHz | 25 kHz |
100 kHz | 50 kHz | 25 kHz |