Warning RX-24F has been discontinued.
|Baud Rate||7343 bps ~ 1 Mbps|
|Running Degree||0° ~ 300°
|Dimensions (W x H x D)||35.6mm x 50.6mm x 35.5mm|
|Gear Ratio||193 : 1|
|Stall Torque||2.6 N*m (at 12V, 2.4A)|
|No Load Speed||126rpm (at 12V)|
|Operating Temperature||-5°C ~ +80°C|
|Input Voltage||9 ~ 12V (Recommended : 11.1V)|
|Command Signal||Digital Packet|
|Protocol Type||Half Duplex Asynchronous Serial Communication
(8bit, 1stop, No Parity)
|Physical Connection||RS485 Multi Drop Bus(Daisy Chain Type Connector)|
|ID||0 ~ 253|
|Feedback||Position, Temperature, Load, Input Voltage, etc|
|Material||Full Metal Gear, Engineering Plastic Body|
The Control Table is a structure of data implemented in the DYNAMIXEL. Users can read a specific Data to get status of the DYNAMIXEL with Read Instruction Packets, and modify Data as well to control DYNAMIXEL with WRITE Instruction Packets.
The Control Table is a structure that consists of multiple Data fields to store status of the DYNAMIXEL or to control the DYNAMIXEL. Users can check current status of the DYNAMIXEL by reading a specific Data from the Control Table with Read Instruction Packets. WRITE Instruction Packets enable users to control the DYNAMIXEL by changing specific Data in the Control Table. The Address is a unique value when accessing a specific Data in the Control Table with Instruction Packets. In order to read or write data, users must designate a specific Address in the Instruction Packet. Please refer to Protocol 1.0 for more details about Instruction Packets.
Note Two’s complement is applied for the negative value. For more information, please refer to Two’s complement from Wikipedia.
The Control Table is divided into 2 Areas. Data in the RAM Area is reset to initial values when the DYNAMIXEL is turned on (Volatile). On the other hand, modified data in the EEPROM Area keeps their values even when the DYNAMIXEL is turned off (Non-Volatile). Data in the EEPROM Area can only be changed or modified when the value of Torque Enable(24) is ‘0’ and Dynamixel is in idle state.
The Size of data is 1 or 2 bytes depend on their usage. Please check the size of data when updating the data with an Instruction Packet. 2 bytes data will be saved according to Little Endian.
The Control Table has two different access properties. ‘RW’ property stands for read and write access permission while ‘R’ stands for read only access permission. Data with the read only property cannot be changed by the WRITE Instruction. Read only property(‘R’) is generally used for measuring and monitoring purpose, and read write property(‘RW’) is used for controlling DYNAMIXEL.
Each data in the Control Table is restored to initial values when the DYNAMIXEL is turned on. Default values in the EEPROM area are initial values of the DYNAMIXEL (factory default settings). If any values in the EEPROM area are modified by a user, modified values will be restored as initial values when the DYNAMIXEL is turned on. Initial Values in the RAM area are restored when the DYNAMIXEL is turned on.
|0||2||Model Number||Model Number||R||24|
|2||1||Firmware Version||Firmware Version||R||-|
|4||1||Baud Rate||Communication Speed||RW||34|
|5||1||Return Delay Time||Response Delay Time||RW||250|
|6||2||CW Angle Limit||Clockwise Angle Limit||RW||0|
|8||2||CCW Angle Limit||Counter-Clockwise Angle Limit||RW||1023|
|11||1||Temperature Limit||Maximum Internal Temperature Limit||RW||80|
|12||1||Min Voltage Limit||Minimum Input Voltage Limit||RW||60|
|13||1||Max Voltage Limit||Maximum Input Voltage Limit||RW||190|
|14||2||Max Torque||Maximun Torque||RW||1023|
|16||1||Status Return Level||Select Types of Status Return||RW||2|
|17||1||Alarm LED||LED for Alarm||RW||36|
|18||1||Shutdown||Shutdown Error Information||RW||36|
|24||1||Torque Enable||Motor Torque On/Off||RW||0|
|25||1||LED||Status LED On/Off||RW||0|
|26||1||CW Compliance Margin||CW Compliance Margin||RW||1|
|27||1||CCW Compliance Margin||CCW Compliance Margin||RW||1|
|28||1||CW Compliance Slope||CW Compliance Slope||RW||32|
|29||1||CCW Compliance Slope||CCW Compliance Slope||RW||32|
|30||2||Goal Position||Target Position||RW||-|
|32||2||Moving Speed||Moving Speed||RW||-|
|34||2||Torque Limit||Torque Limit(Goal Torque)||RW||ADD 14&15|
|36||2||Present Position||Present Position||R||-|
|38||2||Present Speed||Present Speed||R||-|
|40||2||Present Load||Present Load||R||-|
|42||1||Present Voltage||Present Voltage||R||-|
|43||1||Present Temperature||Present Temperature||R||-|
|44||1||Registered||If Instruction is registered||R||0|
|48||2||Punch||Minimum Current Threshold||RW||32|
This address stores model number of the DYNAMIXEL.
This address stores firmware version of the DYNAMIXEL.
The ID is a unique value in the network to identify each DYNAMIXEL with an Instruction Packet. 0~252 (0xFC) values can be used as an ID, and 254(0xFE) is occupied as a broadcast ID. The Broadcast ID(254, 0xFE) can send an Instruction Packet to all connected DYNAMIXELs simultaneously.
Note Please avoid using an identical ID for multiple DYNAMIXELs. You may face communication failure or may not be able to detect Dynamixels with an identical ID.
Baud Rate determines serial communication speed between a controller and DYNAMIXELs.
|Value||Baud Rate(bps)||Margin of Error|
Note Less than 3% of the baud rate error margin will not affect to UART communication.
After the DYNAMIXEL receives an Instruction Packet, it delays transmitting the Status Packet for Return Delay Time (9). For instance, if the Return Delay Time(9) is set to ‘10’, the Status Packet will be returned after 20[μsec] when the Instruction Packet is received.
|2[μsec]||0 ~ 254||Default value ‘250’(500[μsec]), Maximum 508[μsec]|
The angle limit allows the motion to be restrained. The range and the unit of the value is the same as Goal Position(Address 30, 31).
- CW Angle Limit: the minimum value of Goal Position(Address 30, 31)
- CCW Angle Limit: the maximum value of Goal Position(Address 30, 31) The following two modes can be set pursuant to the value of CW and CCW.
|Operation Type||CW / CCW|
|Wheel Mode||both are 0|
|Joint Mode||neither are 0|
The wheel mode can be used to wheel-type operation robots since motors of the robots spin infinitely. The joint mode can be used to multi-joints robot since the robots can be controlled with specific angles.
|About 1°C||0 ~ 100|
Caution Do not set the temperature lower/higher than the default value. When the temperature alarm shutdown occurs, wait 20 minutes to cool the temperature before re-use. Keep using the product when the temperature is high can cause severe damage.
It is the operation range of voltage.
|About 0.1V||50 ~ 250||5.0 ~ 25.0V|
For example, if the value is 80, the voltage is 8V. If Present Voltage(42) is out of the range, Voltage Range Error Bit (Bit0) of Status Packet is returned as ‘1’ and Alarm is triggered as set in the addresses 17 and 18.
It is the torque value of maximum output. 0 to 1,023 (0x3FF) can be used, and the unit is about 0.1%. For example, Data 1,023 (0x3FF) means that Dynamixel will use 100% of the maximum torque it can produce while Data 512 (0x200) means that Dynamixel will use 50% of the maximum torque. When the power is turned on, Torque Limit (Address 34 and 35) uses the value as the initial value.
This value decides how to return Status Packet when Dynamixel receives an Instruction Packet.
|0||PING Instruction||Status Packet will not be returned for all Instructions|
|Status Packet will be returned only for READ Instruction|
|2||All Instructions||Status Packet will be returned for all Instructions|
Note If the ID of Instruction Packet is set to Broad Cast ID(0xFE), Status Packet will not be returned for READ and WRITE Instructions regardless of Status Return Level. For more details, please refer to the
Status Packet section for Protocol 1.0 or Protocol 2.0.
Dynamixel can protect itself by detecting errors occur during the operation. The errors can be set are as the table below.
|Bit 6||Instruction Error||When undefined Instruction is transmitted or the Action command is delivered without the reg_write command|
|Bit 5||Overload Error||When the current load cannot be controlled with the set maximum torque|
|Bit 4||CheckSum Error||When the Checksum of the transmitted Instruction Packet is invalid|
|Bit 3||Range Error||When the command is given beyond the range of usage|
|Bit 2||OverHeating Error||When the internal temperature is out of the range of operating temperature set in the Control Table|
|Bit 1||Angle Limit Error||When Goal Position is written with the value that is not between CW Angle Limit and CCW Angle Limit|
|Bit 0||Input Voltage Error||When the applied voltage is out of the range of operating voltage set in the Control Table|
It is possible to make duplicate set since the function of each bit is run by the logic of ‘OR’. That is, if 0x05 (binary 00000101) is set, both Input Voltage Error and Overheating Error can be detected. If errors occur, in case of Alarm LED, the LED blinks; in case of Alarm Shutdown, the motor output becomes 0 % by resetting the value of Torque Limit(34) to 0.
|0||Turn off the torque(Free run state)|
|1||Turn on the torque and lock EEPROM area|
Turn on or turn off the LED on Dynamixel.
|0(Default)||Turn OFF the LED|
|1||Turn ON the LED|
It exists in each direction of CW/CCW and means the error between goal position and present position. The range of the value is 0~255, and the unit is the same as Goal Position.(Address 30,31) The greater the value, the more difference occurs.
It exists in each direction of CW/CCW and sets the level of Torque near the goal position. Compliance Slope is set in 7 steps, the higher the value, the more flexibility is obtained. Data representative value is actually used value. That is, even if the value is set to 25, 16 is used internally as the representative value.
|Step||Data Value||Data Representative Value|
|1||0(0x00) ~ 3(0x03)||2(0x02)|
|2||4(0x04) ~ 7(0x07)||4(0x04)|
Compliance is to set the control flexibility of the motor. The following diagram shows the relationship between output torque and position of the motor.
It is a position value of destination. 0 ~ 1,023 (0x3FF) is available. The unit is 0.29°. If Goal Position is out of the range, Angle Limit Error Bit (Bit 1) of Status Packet is returned as ‘1’ and Alarm is triggered as set in Alarm LED/Shutdown.
The picture above is the front view of Dynamixel
Note If it is set to Wheel Mode, Goal Position value is not used.
It is a moving speed to Goal Position. The range and the unit of the value may vary depending on the operation mode.
0 ~ 1,023(0x3FF) can be used, and the unit is about 0.111rpm.
If it is set to 0, it means the maximum rpm of the motor is used without controlling the speed.
If it is 1023, it is about 114rpm.
For example, if it is set to 300, it is about 33.3 rpm.
NotePlease check the maximum rpm of the Dynamixel. The motor cannot exceed the maximum rpm with the higher Moving Speed value.
0 ~ 2,047(0x7FF) can be used, the unit is about 0.1%.
If a value in the range of 0 ~ 1,023 is used, it is stopped by setting to 0 while rotating to CCW direction.
If a value in the range of 1,024 ~ 2,047 is used, it is stopped by setting to 1,024 while rotating to CW direction.
That is, the 10th bit becomes the direction bit to control the direction.
In Wheel Mode, only the output control is possible, not speed.
For example, if it is set to 512, it means the output is controlled by 50% of the maximum output.
It is the value of the maximum torque limit. 0 ~ 1,023(0x3FF) is available, and the unit is about 0.1%. For example, if the value is 512, it is about 50%; that means only 50% of the maximum torque will be used. If the power is turned on, the value of Max Torque (Address 14, 15) is used as the initial value.
Note If the function of Alarm Shutdown is triggered, the motor loses its torque because the value becomes 0. Once error conditions are resolved and this value is changed to the value other than 0, the motor can be operated again.
It is the current position value of Dynamixel. The range of the value is 0~1023 (0x3FF), and the unit is 0.29 degree.
The picture above is the front view of Dynamixel.
Caution If it is set to Wheel Mode, the value cannot be used to measure the moving distance and the rotation frequency.
It is the present moving speed. 0~2,047 (0x7FF) can be used. If a value is in the rage of 0~1,023, it means that the motor rotates to the CCW direction. If a value is in the rage of 1,024~2,047, it means that the motor rotates to the CW direction. That is, the 10th bit becomes the direction bit to control the direction, and 0 and 1,024 are equal. The unit of this value varies depending on operation mode.
The unit is about 0.111rpm. For example, if it is set to 300, it means that the motor is moving to the CCW direction at a rate of about 33.3rpm.
The unit is about 0.1%. For example, if it is set to 512, it means that the torque is controlled by 50% of the maximum torque to the CCW direction.
It means currently applied load. The range of the value is 0~2047, and the unit is about 0.1%. If the value is 0~1,023, it means the load works to the CCW direction. If the value is 1,024~2,047, it means the load works to the CW direction. That is, the 10th bit becomes the direction bit to control the direction, and 1,024 is equal to 0. For example, the value is 512, it means the load is detected in the direction of CCW about 50% of the maximum torque.
|Bit||15 ~ 11||10||9 ~ 0|
|Value||0||Load Direction||Data (Load Ratio)|
Note CCW Load : Load Direction = 0, CW Load : Load Direction = 1
Note Present load is an inferred value based on the internal output value; not a measured value using torque sensor, etc. Therefore, it may be inaccurate for measuring weight or torque. It is recommended to use it for predicting the direction and size of the force being applied to the joint.
It is the size of the present voltage supplied. This value is 10 times larger than the actual voltage. For example, when 10V is supplied, the data value is 100 (0x64) If Present Voltage(42) value is out of range, Voltage Range Error Bit (Bit0) of Status Packet is returned as ‘1’ and Alarm is triggered and set the address 17 and set 1 to the Bit 0 of the address 18.
It is the internal temperature of Dynamixel in Celsius.
Data value is identical to the actual temperature in Celsius. For example, if the data value is 85 (0x55), the current internal temperature is 85°C.
|0||REG_WRITE instruction is not received|
|1||REG_WRITE instruction is received|
Note If ACTION instruction is executed, the value will be changed to 0.
|0||Goal position command execution is completed|
|1||Goal position command execution is in progress|
|0||EEPROM area can be modified|
|1||EEPROM area cannot be modified|
Caution If Lock is set to 1, the power must be turned off and then turned on again to change into 0.
Minimum current to drive motor. This value ranges from 0x20 to 0x3FF.
- FR07-B1 Option Frame
- FR07-H1 Option Frame
- FR07-S1 Option Frame
- FR07-B101 Option Frame
- FR07-F101, FR07-X101 Option Frame
- FR07-H101 Option Frame
- FR07-S101 Option Frame
- HN07-N1 Horn
- HN07-I1 Horn
- HN07-T1 Horn
- HN07-N101 Horn
- HN07-I101 Horn
- HN07-T101 Horn
The horn is installed on the front wheel gear serration of the DYNAMIXEL whereas the bearing set is installed on the back.
Installing the Horn
Place the thrust horn washer into the actuator before inserting the horn. You must carefully align the horn to the wheel gear serration by aligning dots.
Once alignment is properly done, gently push the center of the horn toward the actuator. Make sure that the horn washer is in place as you tighten the bolt.
Installing the Bearing Set
You may need to remove the bearing set from the previous actuator and reinstall it into the new actuator. The bearing set can also be purchased separately. As bearing set is rotating freely, therefore alignment is not required when assembling to DYNAMIXEL.
Note Compatibility Guide
|Crimp Terminal||MOLEX 80-70-1039|
|Wire Gauge||21 AWG|
To control the Dynamixel actuators, the main controller needs to convert its UART signals to the half duplex type. The recommended circuit diagram for this is shown below.
The power of Dynamixel is supplied via Pin1(-), Pin2(+).
(The above circuit is built into Dynamixel-only controller.)
In the above circuit diagram, the direction of data signal of TxD and RxD in the TTL Level is determined according to the level of DIRECTION 485 as follows:
In case of DIRECTION485 Level = High: The signal of TxD is output to D+ and D-
In case of DIRECTION485 Level = Low: The signal of D+ and D- is output to RxD