2nd German-West African Conference on Sustainable, Renewable Energy Systems SusRES – Kara 2021 

Intelligent Automation & Robotics 

https://doi.or/10.52825/thwildauensp.v1i.11 

© Authors. This work is licensed under a Creative Commons Attribution 4.0 International License 

Published: 15 June 2021 

Development and Manufacturing of a controlled 3D 
printed bionic hand 

H. Smajic 1[https://orcid.org/0000-0002-0669-1979], T. Duspara 1[https://orcid.org/0000-0002-6985-5950] 
1 Technische Hochschule Köln 

Abstract. During a current project, a fully functioning prototype of a 3D printed bionic hand 
was developed. This paper explains principles such as: bionic hand movement, working rules 
of sensors and actuators etc. Design of all parts are performed, including the wiring of control 
system. The project includes two types of sensor control systems for bionic hand. One is with 
stretch sensors that replicates movement of human hand onto the bionic model. Other type is 
using machine learning (AI) and a camera. The average amputee cost is $30.000,00 for a 
new custom-built arm/hand. With the advancement of technology through time, 
manufacturing processes became cheaper and more accessible. Technical innovation of this 
project was the fact, that a functional prosthetic hand prototype was built for price lower than 
$50,00. The prototype does not have all the functions and capabilities as the full priced 
custom prosthetic hand, but it can replicate altogether the movements as the real device. All 
the fingers are capable of moving individually, sideways and with the work on the new 
version, gripping function could be perfected. Further work on materials, could help find the 
adequate material to increase friction and thusly enhance the grasp strength. The new 
challenge would involve testing with different kinds of materials to improve the working 
stability. As it was already unfavorable, this project was mostly based onto the actuation part, 
or rather the hand itself. Second part of research would involve exploring of different sensor 
systems. Two control solutions were designed and tested. Next steps would involve 
neurotransmission sensors, where arm would be controlled using brainwaves as signals that 
are transformed in movement. 
Keywords: bionic hand, AI, 3D printing, low-budget  

Introduction 

Main goal while building a prosthetic hand is to replicate all the movements as a human hand 
has. To achieve desired movement, all bones of a human hand must be replicated and 
designed. 3D printed prosthetic hands are well known in 21st century but unfortunately, they 
are not widely used because of durability of the 3D printed material. With further 
advancement of technology, improvements of composite materials are inevitable.  

Mechanical parts 

A human hand consists of three basic bone groups. Those are phalanges, metacarpals and 
carpals. To design a 3D model of a hand, same bone parts should be engineered. Those are 
distal phalanx, middle phalanx and proximal phalanx. The main function of hand can be 
recreated and engineered using only phalanges, so metacarpal and carpal bones will be 
merged into a one piece.  

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Fingers (Phalanges) - Distal phalanx is the tip of the finger. On a 3D model of this 
part, a pre designed holes can be found. These include holes for the shaft, and grooves for 
the strings. Going from up to down, next part is the middle phalanx which is placed into the 
distal phalanx and secured with said shaft. On the top and the bottom of middle phalanx 
there are enter and exit holes for the string. Proximal phalanx represents the lowest phalanx 
bone. This is the last moving part of the bionic hand. It is the largest phalanx bone with the 
maximum length of approximately 60mm. It is connected to the rest of the hand using a 
connector and two shafts. The upper shaft is the same as with the two earlier mentioned 
bones. Lower shaft connects it to the central part of the hand which represents the merged 
metacarpal and carpal bones. The difference between two shafts is the freedom of 
movement. Upper shaft allows the piece to move towards and away from the palm. Lower 
shaft allows the movement of whole finger in a sideways direction. Because phalanges are 
connected to each other, movement of proximal phalanx sideways results in the movement 
of whole finger. Unlike the other fingers thumb consists of only two parts but it has the ability 
to move into two different directions. Bottom part of the thumb is actually a holder for a servo 
motor that rotates the thumb around its nominal axis. As well as with other fingers, string is 
placed through the thumb thus achieving the regular movement towards the palm, or in other 

words, the „grip“ itself.  
Palm - As the movement of metacarpal and carpal bones is minimal, they will be 

replaced with a single piece that represents the palm of a bionic hand. Each finger has one 
string with two endpoints. Pulling one endpoint moves the finger towards the palmand other 
endpoint moves that guide the strings. It is crucial to design the blockers for each individual 
finger. These blockers are placed on the back side of the finger-palm connectors. When the 
finger goes from fully the finger back into the first position. To avoid confusion and mess, the 
palm has holes closed to fully open position, the proximal phalanx hits the blocker and stays 
in place. 

Distal phalanx 

Middle phalanx Proximal phalanx 

Blocker 

Palm 

Servo mount 

Shafts 

Servo 

1mm 
Shafts 

M3 Shafts 

String 
holes 

Blockers 

Figure 1. Phalanges Assembly. 

Figure 2. Palm Assembly. 
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Arm and stand design - While designing the arm the crucial thing to do is to provide 
slots for the servo motors. Arm model is compact and has slots for six servo motors. To 
avoid the collision between levers of servo motors, half of the servos are facing the front side 
and the other half are facing the back side. The stand is placed at the bottom of the hand. To 
lower the center of mass, and prevent falling of the hand due to movement inertia, a 0,5kg 
weight is added to the stand. The lower part of the arm fits snuggly into the stand. Stand is 
the last part of the mechanical assembly. In order to test the prototype, a housing was 
designed, which fits all the electronical components. 

Strings - For the movement of fingers or in other word the connection between phalanges 
and servo motor, a fishing nylon is used. The one used for prototype is 0.2mm thick and it 
has the load strength of 20[N] which is more than enough to support the force required to 
achieve movement of the hand. Each piece of nylon string is cut to the size of approximately 
600mm. This string is pulled through all of the phalanges in a way that the two endpoints 
beneath the arm are equally long. The center of string is glued on top of the distal phalanx of 
each finger. Later on the string goes through the holes inside the palm and finally through the 
arm-palm connector and to the servo motors placed on the arm. The string is pulled through 
holes on servo levers and secured with adhesive. Before securing the string itself, a proper 
movement should be checked. If everything is moving according to the plan, the strings can 
be attached onto the lever. For entire assembly, less than 3m of nylon are needed. Nylon is 
very cheap so material cost does not affect overall price. 

Actuators 

Actuators are devices that provide movement for the assembly. Micro servomotors are 
chosen because of their compact design and easy control. A servomotor is a rotary or linear 
actuator that allows for precise control of angular or linear position, velocity and 
acceleration. They can easily be mounted onto the arm part. For the full movement of the 
hand, seven servomotors are required. Five motors enable the movement of five fingers 
where the sixth motor enables the rotational movement of the thumb. The seventh motor is 
used for sideways movement of fingers. Servomotors can rotate their shaft for 180 degrees. 
The servo lever should be around 35mm long. If the lever is shorter, the finger doesn’t reach 
the end positions. There are two positions of the motors that are used for the movement. The 
180-degree position places the finger fully open and 0 degree moves the finger back into its 

Servo Lever 

Micro Servo 

M3 Screw 

Arm  

Weight holder 

Electronics housing Arduino 

Arm holder 

Figure 3. Arm assembly. 

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first point. Servomotors used for prototype have metal gears inside them which makes them 
more durable. Another benefit from these motors is their price. For achieving the basic 
movements, seven servo motors are needed which in the end, adds up to the price of 
19,99€.  

Production process 

Process of building a hand can be classified in five phases: 
1. CAD/CAM Design 
2. Manufacturing 
3. Quality control 
4. Assembly 
5. Automation 

CAD/CAM Design 

Phase one includes scaling of the parts, so they can perfectly fit individual person. Each part 
needs to be scaled by certain percentage depending on the size of the hand. Scaling is done 
using a CAD software (SolidWorks, NX, etc.). After the scaling is done, an animation must be 
ran. Animation shows potential problems and irregularities without the necessity for a 
prototype. When animation shows solid work and movement of all the parts, each part needs 

to be converted into triangulated surface-s commonly known as STL files. Converted files are 
then imported into a CAM software. Software used is called “Slic3r” and it is utilized for 3D 
printer CAM preparation. CAM software takes the STL files, and later on computes the 
coordinates used for the printer movement, based on selected parameters. Parameters 
include: print, printer and material specifications. Most important are the print specifications, 
whereas other two depend on the specific machines that are used. Parts need to be 
manipulated and positioned on the print bed in a way that conserves the space on the 
printing surface. After thorough calibration and testing, the ideal parameters can be chosen. 
The ones chosen for this particular print and printer are shown in table below. 
 
 
 

Figure 4. CAM Preparation. 

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Table 1. Printing parameters. 

 
 
 
 
 
 

Manufacturing 

When the parameters are all set, CAM software generates G-code used for the print. Parts 
are made out of ABS filament with 50% infill. Filament has 1.75mm diameter, so it is easy to 
calculate its mass. One spool of ABS material contains 290,7 meters of filament (1kg spool). 
Printers surface has printable area of 20x20cm. In regard to that, two separate G-Code files 
must be created to fit all the parts of a bionic hand. Printing process for entire hand uses 
89,5m of ABS filament which weighs 308g. The main benefit behind this project is its “Low-
cost factor”. ABS filament spool costs around 20,00€, so mechanical parts can be 
manufactured with this technology for only 4,52€. This means, that you can create all the 
mechanical moving parts of a bionic hand for under 5,00€ thanks to the advancement of 
manufacturing processes and technologies.  

Table 2. Material expenses. 

According to the table above and earlier mentioned price of servomotors, overall assembly 
worth does not exceed 25,00€. In abstract there was a 50,00€ price mentioned for the 
assembly. This price consists of labor (staff), disposable material, screws etc. 

Quality control 

After the manufacturing process, which takes a little more than 30 hours, it is time to clean 
the parts and check dimensions. Support material must be removed from surfaces, and 
surfaces should be grinded. In order to achieve perfect clearance in between parts, all the 
dimensions must be checked and compared to the dimensions in CAD drawing. If some of 
the dimensions are unequal to the ones in the drawing, they must be corrected. Perfect gap 
between two parts can be tested after adding a shaft between them. If the parts move one 
around another smoothly and without any problems collide with their limit stops (blockers), 
then the clearance is fine and shaft can be fixed in place. If the movement seems too rough, 
then contact surfaces need to be grinded 0,2 ~ 0,4mm. This process is repeated for each 
connecting part until the clearance is satisfactory.  
 
 

 Parameter Value Unit 
P

ri
n

ti
n

g
 s

e
tt

in
g

s
 

Layer height 0.16 mm 
Fill density 50%  
Fill pattern Triangle  

Printing speed 
Outer perimeters 20 mm/s 
Other perimeters 25 mm/s 

 30 mm/s 
Skirt  1 loops 
Brim  5 mm 
Generate support material: YES  
Overhang threshold: 65%  

Print No. Pieces 
Filament 
length [m] 

Fillament 
mass [g] 

Layer 
count 

Print 
time 

Cost 
[€] 

Print 1 22 59,242 203,78 1107 22:24:33 2,99 
Print 2 13 30,271 104,12 312 07:59:01 1,53 
Altogether 35 89,513 307,91 1419 30:23:34 4,52 

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Assembly 

Assembly phase starts after acquisition of all parts and components. Micro servomotors are 
placed into slots on the arm and secured in place with M3 screws. To extend servo levers, 
new longer levers were made and placed onto the existing ones. When all the mechanical 
parts are printed and dimensions are checked, all the parts should be lined up one next to 
another. Next phase is pushing the string through predesigned grooves on the phalanx’s 
parts. This process requires a lot of patience.  

The grooves are very narrow and due to the imperfections of printing material, it is common 
for the strings to stick. After all the strings have been pulled through phalanges and palm, the 
shafts are mounted. At this point, string ends are equal length and they are secured at the 
top of distal phalanx with glue. Pulling the two endpoints will result in opening or closing 
fingers. If the movement is as desired, endpoints must be linked with servo levers. Before 
firmly securing string to servo levers, movement is checked by carefully rotating the axis of 
servomotor. Zero-degree position results in fully open finger whereas 180-degree position 
results in fully closed finger. When all the movements are examined and approved, strings 
are secured to servo levers with adhesive and leftover can be cut off.  

Automation 

With fully assembled hand, the means of control must be constructed. Control system 
requires a microcontroller that moves servomotors. Microcontroller used in this project is an 
Arduino Nano microcontroller. Arduino nano has 13 digital I/O pins. For control of the 
actuators, each servo requires one PWM output pin. That means that seven output pins are 
used for the servo movement. Generally Arduino can supply voltage to actuate these servos, 
but because there are seven servos attached to this assembly, Arduino voltage output 
cannot provide enough current to move all of them simultaneously. Additional power source 
is added to raise the current in servos. For this project a 20W power source is used. This 
provides servos with 5V of voltage and 4 Ampers of current. To connect all the servos to 
Arduino, a custom PCB bord was designed. On one end of the board there is a standard 

Figure 5. Full assembly of a bionic hand. 

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voltage connector. The plus pin of voltage connector is soldered to the VIN pin of Arduino. 
This provides the power that Arduino needs to operate without additional power source 
(USB). The same pin is connected to all of the middle pins of servo connector. Other pin is 
soldered to the Arduino GND pin. With this, all the devices including servos and Arduino are 
powered with the same power source. The USB connector on the Arduino is only used to 
transfer the code from the computer to the microcontroller.  

Conclusion 

During the work on this project, a final prototype was built. The average amputee pays tenths 
of thousands of Euros for a new custom-built arm/hand. With the advancement of technology 
through time, manufacturing processes became cheaper and more reachable. Technical 
innovation of this project was the fact, that a functional prosthetic hand prototype was built for 
under 30,00€. This prototype does not have all the functions and proficiency as the full priced 
prosthetic hand, but it can replicate all the movements as the real device. All the fingers are 
capable of moving individually, sideways and with the work on the new version, gripping 
function could be perfected. Further work on materials, could help find the adequate material 
to increase friction and thusly enhance the grasp strength. Further work on this project would 
involve experimentation with different kinds of materials to improve the operational stability. 
As it was already said, this project was mostly based onto the actuation part, or rather the 
hand itself. Second part of research would involve exploring of different sensor systems. 
Interesting potential was noticed in works with neurotransmission sensors. Next phase could 
involve synthesis of a low budget 3D printed bionic hand with said sensors.  

References 

1 Taylor C, Scwarz R. The Anatomy and Mechanics of the Human Hand. Artificial 
Limbs . 1955;2(2):22-35. 

2 Shi W, Lyu Z, Tang S, Chia T, Yang C. A bionic hand controlled by hand gesture 
recognition based on surface EMG signals: A preliminary study. Biocybernetics and 
Biomedical Engineering. 2018;38(1):126-135. 
https://doi.org/10.1016/j.bbe.2017.11.001 

Figure 6. PCB Design. Figure 7. Wiring schematic. 

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3 Bronzino J, Peterson D. Biomedical engineering fundamentals. 2nd Edition. CRC 
Press; 2014. https://doi.org/https://doi.org/10.1201/b15482 

4 Clement R, Bugler K, Oliver C. Bionic prosthetic hands: A review of present 
technology and future aspirations. The Surgeon. 2011 Dec;9(6):336-340. 
https://doi.org/10.1016/j.surge.2011.06.001 

5 Aman M, Sporer ME, Gstoettner C, Prahm C, Hofer C, Mayr W, Farina D, Aszmann 
OC. Bionic hand as artificial organ: Current status and future perspectives. Artificial 
Organs. 2019 02;43(2):109-118. https://doi.org/10.1111/aor.13422 

6 Syed A, Agasbal ZTH, Melligeri T, Gudur B. Flex Sensor Based Robotic Arm 
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2012;05(05):364-366. https://doi.org/10.4236/jsea.2012.55042 

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	23_11-Smajic-etal_Conference paper-16-1-6-20210506
	Introduction
	Mechanical parts
	Actuators
	Production process
	CAD/CAM Design
	Manufacturing
	Quality control
	Assembly
	Automation
	Conclusion
	References