Brushless Drive: Unterschied zwischen den Versionen
BerndS (Diskussion | Beiträge) |
BerndS (Diskussion | Beiträge) |
||
| Zeile 36: | Zeile 36: | ||
The ArduMover Brushless Drive Unit consist of 3 main parts, the gearbox, the brushless motor and the motor driver electronic. The gearbox and the motor are factory assembled and will be delivered as one unit. | The ArduMover Brushless Drive Unit consist of 3 main parts, the gearbox, the brushless motor and the motor driver electronic. The gearbox and the motor are factory assembled and will be delivered as one unit. | ||
| − | [[Datei:BLUnit.JPG|400px|thumb | + | [[Datei:BLUnit.JPG|400px|thumb|ArduMower Brushless Drive Unit]] |
The Brushless Motor Driver electronic board will be delivered as a construction kit with pre soldered SMD electronic components. The user must place and solder only one capacitor (1500uF or 2200uF) and 5 plug sockets. This is valid for all variation of the kits, we will describe later! | The Brushless Motor Driver electronic board will be delivered as a construction kit with pre soldered SMD electronic components. The user must place and solder only one capacitor (1500uF or 2200uF) and 5 plug sockets. This is valid for all variation of the kits, we will describe later! | ||
| Zeile 45: | Zeile 45: | ||
This device has verry interesting specifications for our ArduMower, which are users right now, but also in the future for further implementation of new functions. | This device has verry interesting specifications for our ArduMower, which are users right now, but also in the future for further implementation of new functions. | ||
| − | Here some important specifications: | + | |
| + | |||
| + | == Here some important specifications: == | ||
- Operating Supply Voltage 8.5V to 32 V | - Operating Supply Voltage 8.5V to 32 V | ||
| − | |||
- Operating junction temperature range (Contr. & MOSFETs) -40°C – 150°C | - Operating junction temperature range (Contr. & MOSFETs) -40°C – 150°C | ||
| − | |||
- MOSFET continues current max. 8A / peak current 108A (we use max.3,5A Fuse ) | - MOSFET continues current max. 8A / peak current 108A (we use max.3,5A Fuse ) | ||
| − | |||
- Integrated Overcurrent, Overvoltage and Overtemperature Protection | - Integrated Overcurrent, Overvoltage and Overtemperature Protection | ||
| − | |||
- HAL Sensor loop back, to stabilize the motor speed automatically by the DRV | - HAL Sensor loop back, to stabilize the motor speed automatically by the DRV | ||
| − | |||
- Individual programmable motor parameter for different motor designs | - Individual programmable motor parameter for different motor designs | ||
| − | |||
- Motor speed control by PWM, impulse or SPI interface (software, register controlled) | - Motor speed control by PWM, impulse or SPI interface (software, register controlled) | ||
The main advantage of this controller is the flexibility, to optimize the controller parameter individually for different motor types &HAL sensors and optimize the parameter for each motor type. | The main advantage of this controller is the flexibility, to optimize the controller parameter individually for different motor types &HAL sensors and optimize the parameter for each motor type. | ||
| − | + | But the advantage is on the other hand also the disadvantage. Without programming, the Brushless Driver board it is not working. Before you can use the device, you have to write your motor parameter in the OTP (one-time programmable) non-volatile memory. Once programmed, the DRV uses this parameter by default, during power up. | |
IMORTANT : The OTP can only programmed ONE time! OTP changes afterwards are not possible. | IMORTANT : The OTP can only programmed ONE time! OTP changes afterwards are not possible. | ||
But via SPI, all register parameters can be changed during operation and they will be active until power down the Board. By powering up again, the original OTP parameter will be used. | But via SPI, all register parameters can be changed during operation and they will be active until power down the Board. By powering up again, the original OTP parameter will be used. | ||
Version vom 14. Januar 2021, 15:14 Uhr
ArduMower Brushless Drive
....under construction!!
Why brushless and what are the advantages?
A brushless motor offer several advantages over brushed DC motors. The main advantages are high torque to weight ratio / same power by smaler case design, more torque per watt / better energy efficiency / longer motor worktime per battery cycle , increased reliability, reduced noise, longer lifetime because of no brush and commutator erosion, and an overall reduction of maintenance and service cost.
The disadvantage is, a brushless motor and his driver are much more expensive than a brushed DC motor. But if you see the total cost over ArduMower live time, you will see an overall cost reduction abd a very fast return on investment, especially for large lawn area. The cost advantage will take place after 2-4 years (depends on loan area and mower usage), by end of life of the brushes and commutator of an DC Motor, where you have to replace the DC Motor by a new one. So for high usage on large areas, you will amortize the higher invest within 2 or 3 years and save a lot of money.
Out of this pro and cons you can select the right drive solution for your ArduMower.
DC motor drive : small loan area, less working hours of the ArduMower per week.
Brushless drive: large loan areas and 5-7 days / week usage of the ArduMower. Longer working period per battery charging cycle.
ArduMower drive concept
Since 2021, the ArduMower project supports a wide scale of drive options. From the powerful and cost efficient DC motor over the special AduMover Brushless Drive for larger power drive up to high power drive with commercial brushless controllers. The DC and the AduMover Brushless Drive are supported by the community and the parts will be availably in the online shop [1]. The high power drive is very special and needs some individual adaptions. If you are interested please get in contact with BerndS via ArduMower Forum.
In this part we will not cover the DC motor drive. We will focus on the AduMover Brushless Drive and how to handle it.
ArduMower Drive Concept overview:
ArduMower Brushless Drive :
The ArduMover Brushless Drive Unit consist of 3 main parts, the gearbox, the brushless motor and the motor driver electronic. The gearbox and the motor are factory assembled and will be delivered as one unit.
The Brushless Motor Driver electronic board will be delivered as a construction kit with pre soldered SMD electronic components. The user must place and solder only one capacitor (1500uF or 2200uF) and 5 plug sockets. This is valid for all variation of the kits, we will describe later!
ArduMover Brushless Driver design
The ArduMover Brushless Driver electronic is based on the Texas Instruments Brushless DC Motor Controller DRV8308. This device has verry interesting specifications for our ArduMower, which are users right now, but also in the future for further implementation of new functions.
Here some important specifications:
- Operating Supply Voltage 8.5V to 32 V - Operating junction temperature range (Contr. & MOSFETs) -40°C – 150°C - MOSFET continues current max. 8A / peak current 108A (we use max.3,5A Fuse ) - Integrated Overcurrent, Overvoltage and Overtemperature Protection - HAL Sensor loop back, to stabilize the motor speed automatically by the DRV - Individual programmable motor parameter for different motor designs - Motor speed control by PWM, impulse or SPI interface (software, register controlled)
The main advantage of this controller is the flexibility, to optimize the controller parameter individually for different motor types &HAL sensors and optimize the parameter for each motor type.
But the advantage is on the other hand also the disadvantage. Without programming, the Brushless Driver board it is not working. Before you can use the device, you have to write your motor parameter in the OTP (one-time programmable) non-volatile memory. Once programmed, the DRV uses this parameter by default, during power up.
IMORTANT : The OTP can only programmed ONE time! OTP changes afterwards are not possible.
But via SPI, all register parameters can be changed during operation and they will be active until power down the Board. By powering up again, the original OTP parameter will be used.
