Tag Archives: measurements

Printable Prosthetics R&D Q&A FAQ: Part The Third – The Answering

Posted on by

This slideshow requires JavaScript.

Tuesday afternoon I had the good fortune to talk to Professor Jorge Zuniga of Creighton University regarding his insights on printable prosthetics, measurements of uneffected/effected hands, and various important design considerations.  Getting to talk to him really helped crystallize my understanding of the various measurements and the way in which the parts of the printable prosthetic1

  1. Design Ideals
    1. One of the design ideals of the Cyborg Beast prosthetic is to fashion a device that strives for symmetry with the unaffected hand.  Thus, all of the necessary measurements are taken from the unaffected extremity.  This serves two purposes.  First, it allows for the prosthetic to be similar in scale to the unaffected hand.  Secondly, the unaffected extremity tends to be, in most cases2 , slightly larger than the affected extremity.  The size difference may be due to the unaffected extremity being used more, and thus having more muscle mass, or due to the loss of muscle tone and muscle atrophy in the affected extremity.  Either way, a prosthetic designed using the measurements from the unaffected extremity should generally fit the affected extremity.  Since this particular prosthetic design uses velcro straps to fasten to the affected forearm, a prosthetic that is slightly too large can easily be adjusted to fit well by tightening the straps.
    2. Another design ideal is to create a core prosthetic design which works for the vast majority of persons.
  2. Critical Printable Components
    1. A rough sketch of the various parts of the Cyborg Beast prosthetic appear above as “Figure 2.”
    2. Palm.  This is the part that fits over the hand.
    3. Gauntlet.  This is the part that fits over the forearm, between the wrist and elbow.
    4. Four fingers, each comprised of two pieces.  The above simplified sketch only shows the fingers as a single piece.  Do not let my sophisticated drawings fool you.
    5. One thumb, comprised of two pieces.  Like the fingers, the thumb is comprised of two plastic pieces.
  3. Critical Measurements
    1. These measurements refer to the lines labeled in “Figure 1.”  All measurements relate to the unaffected extremity.
    2. F5.  This is the length of the forearm, from the interior of the elbow to the wrist.  While this could be measured along the side of the forearm, it very likely doesn’t matter.
    3. F2 (measured at 1/2 F5).  At a location along the forearm, half way long F5, the width of the forearm.
    4. H1.  This is the distance across the knuckles, from the pinky to the forefinger.
      1. When I lay my own hand flat on a table top, I perceive that an imaginary line drawn through my pinky and forefinger knuckles would end up being not exactly perpendicular to an imaginary line drawn from my elbow to my wrist.  More on this below.
      2. All of that is another way to say that I suspect H1 is not perpendicular to F5.
    5. W.  This is the width of the wrist.  Rather than being strictly measured from either side of the wrist, this measurement appears to best made using the endpoints of the H2 and H3 lines closest to the wrist.
    6. H2 and H3.  H2 is the length from the wrist to the pinky knuckle and H3 is the length from the wrist to the forefinger knuckle.
    7. All other measurements indicated might possibly be useful for refining the design, but they are primarily important for the Creighton University research study purposes.
  4. How Each Critical Measurement Informs Design
    1. F5.  Gauntlet length is not longer than 1/2 F5 and not shorter than 1/4 F5.
    2. F2.  Gauntlet forearm width is F2.
    3. W.  Gauntlet wrist width is W.  Theoretically, if the prosthetic’s palm is scaled up to accommodate the wrist width (W), the affected hand  should fit under and inside the prosthetic palm.
    4. H3 can be used to inform the relative lengths of the fingers to match the overall length of the unaffected hand.   This isn’t strictly required for a functional prosthetic.  As designed, the Cyborg Beast appears to use fingers of equal length.  However, the fingers could be scaled up or down along with the rest of the prosthetic hand.  Alternatively, and as will be discussed below, its possible that the fingers could be designed to be of different lengths.  Prosthetics for young children should contemplate fingers based upon slightly larger, 1-2cm, measurements.  The reason being that they quickly outgrow existing parts.
  5. Functional Design Considerations
    1. Thickness of parts is 3mm – 5mm, 20% fill.
    2. The wrist hinges should line up as exactly as possible with where the user’s wrist bends.  Additionally, the wrist hinge should be perpendicular to the line of the forearm/gauntlet.
    3. There should be about 1 – 2 mm of space between the hinge part on the palm and the hinge part on the gauntlet.  This allows a washer to be inserted for more fluid movement.
    4. Eliminate square corners when possible, as sharp edges can contribute to possbile injury.
  6. Cosmetic Design Considerations
    1. Using the unaffected hand for measurements also allows us to seek symmetry between the hands.
  7. Advanced Considerations
    1. Degree tilt to H1.  As mentioned above, it seems like the “H1” line is not perfectly perpendicular to an imaginary line drawn from my elbow to my wrist.  An educated guesstimate would be that there is a 9 degree tilt to this line.  While existing Cyborg Beast designs do not include this knuckle “tilt,” including this feature in future designs may allow the prosthetic to appear and function more naturally.  However, I don’t know if there’s any real ergonomic benefit to using incorporating this knuckle tilt.
    2. Different knuckle positions for fingers.  The Cyborg Beast has a knuckle “block” that positions the attachment points for all fingers in a straight line.  The reason for this is simple – it’s a lot easier to put one long screw through the entire knuckle block to secure and strengthen all four fingers at once.  At a recent e-NABLE meeting I had the chance to inspect a 3D printed prosthetic which used different knuckle positions for each finger.  Rather than all of the knuckles in a straight line, this model featured each knuckle at a different, and more natural seeming, position.  While this can appear more natural, I’m not sure there’s an ergonomic or aesthetic benefit.
    3. Different finger lengths.  Fingers are different lengths.  The Cyborg Beast, with all fingers having the same relative knuckle positions and same finger sizes, has a more mechanical look than might otherwise be possible.  I don’t know if there’s an ergonomic benefit to using different finger lengths, but this is certainly something to explore.

Based on the above, I think I’m ready to dive back into the OpenSCAD code and work out a parametric gauntlet, fingers, and thumb.  Stay tuned!

Default Series Title
  1. I’m basing my own designs off of his Cyborg Beast designs []
  2. Let’s just choose the large and arbitrary percentage of 95% []

Printable Prosthetics R&D Q&A FAQ: Part 2 – The Wondering

Posted on by

This slideshow requires JavaScript.

In order for me to design an OpenSCAD parametric model that can be adjusted to work for more people, I need to get a better handle on the necessary measurements and how they effect the final design.  Below is my understanding of the necessary measurements and how those measurements necessitate changes in the final prosthetic.

  1. What are the design ideals, besides functionality?
    1. While answering a different question, Marc Petrykowski suggests, “My goal as the designer and printer is to make the hand as near perfect as the other hand so it feels the same to the body and brain, thus they will respond with the effected hand like it was their real non effected hand. Also as stated above, the degrees of flexion and extension and the size/length of the fingers are all incorporated into the final design before the printing the hand.”
    2. Thus, all other things being equal, he tries to craft a hand that is as similar as possible to the non-effected hand.
  2. What are the main parts of the Cyborg Beast?
    1. I’ve drawn a picture with the main features of the Cyborg Beast printable prosthetic.  There are really just a few parts – the palm, the “gauntlet,” fingers, and thumb.  The gauntlet fits over and is secured to the forearm and is connected to the palm by two hinges.  The palm goes over the user’s effected hand and is connected to the fingers and thumb.
  3. What are the necessary measurements?
    1. Marc Petrykowski has provided a set of photos to demonstrate the various measurements.  They appear to all be in millimeters.  Please forgive my layman’s description of these various measurements.  Measurements are taken of the effected and non-effected sides so that a prosthetic can be made that will fit the effected side, but have similar characteristics to the non-effected side.
    2. Flexion angle.  This would be the maximum angle of movement from holding your hand out and then bending the hand at the wrist towards the inside of the wrist.  An example is pictured above as “Figure 1.”
    3. Extension angle.  This would be the maximum angle of movement from holding your hand out and then bending the hand at the wrist away from the inside of the wrist.  An example is pictured above as “Figure 2.”
    4. Knuckle width.  This is the width of the hand at the knuckles.  In Figure 3, you’ll see this as “H1” and “h1.”
    5. Wrist width.  This is the width of the hand at the wrist.  In Figure 3, you’ll see this as “W” and “w.”
    6. Hand measurements.  I’ve identified these as “H1 – H3” and “h1 – h4” in Figure 3 above.
    7. Forearm width measurements.  I’ve identified these as “F1 – F3” and “f1 – f4” in Figure 3 above.
  4. How does each measurement inform the design?
    1. Again, this is merely my guess, impression, or understanding of how each measurement results in a design change.  For the purposes of these diagrams, I’ve assigned each measurement a letter or letter/number combination.  When applicable, I’ve differentiated between the effected (lower case) and non-effected (upper case) hands.
    2. Hand Measurements (Figure 1,blue and green)
      1. Knuckle width, non-effected hand, “H1”.  This is necessary to creating a prosthetic of the size that will match the non-effected hand.
      2. Knuckle width, effected hand, “h1”.  This is necessary to creating a prosthetic of the size that will fit the effected hand inside the palm.
      3. Wrist to pinky knuckle, “H2” and “h2,” the purpose of which is to ensure a prosthetic that will fit the effected hand inside the palm.
      4. Wrist to middle finger tip, “H3” is the overall length of the uneffected hand.  The purpose of this is to create a prosthetic of roughly the same size as the uneffected hand.
      5. Wrist to index finger knuckle, “h3” is for making sure the prosthetic palm will fit around the effected hand.
      6. Wrist to middle3 finger, “h4” is for making sure the effected hand will fit inside the prosthetic palm.
    3. Wrist Measurements (Figure 1, orange)
      1. Wrist width, “W” for the non-effected hand and “w” for the effected hand.  The purpose of the effected hand measurement is to ensure a good fit between the prosthetic palm and the effected hand and the purpose of the non-effected hand measurement is to allow the prosthetic palm to match the non-effected hand more closely.
    4. Forearm Measurements (Figures 1, purple and red)
      1. Various measurements from “F1” (and “f1) just below the wrist to “F4” (and “f4”) which is the width of the elbow. As best as I can tell, these measurements are to ensure a good fit of the “gauntlet” on the effected forearm.
      2. Elbow to wrist, “F5” on the uneffected arm and “f5” on the effected arm.  I’m not sure what the purpose of this measurement is, but perhaps it is to ensure the effected arm with prosthetic is roughly the same length as the unaffected arm.
    5. Angle Measurements (Figures 2, 3)
      1. Somehow the flexion and extension are incorporated into the design.  I do not know how these settings inform the design.
  5. How accurate do these measurements need to be?
    1. Within 1mm, rounded up would be best.  Thanks to Peregrine Hawthrone and David Orgeman for the input.
  6. Questions begetting questions
    1. If you’ve ever made one of these prosthetics, please let me know if there’s anything I’ve gotten wrong.
    2. It appears the measurements effect the design as follows:
      1. Measurements “h1, h2, h3, h4 and w” dictate the size of the palm.  The ratio of the increase/decrease is then applied to all the finger bits.  The measurement “H3” is used to adjust the size of the palm and fingers on the effected arm.
      2. Measurements “f1, f2, and w” dictate the size of the gauntlet.
      3. The additional measurements on the corresponding uneffected arm could be used to make the prosthetic over the effected arm appear more like the uneffected arm.
      4. I’m guessing the other unused measurements (“f3, f4, f5”) are used as part of the Creighton University research study, to measure the physical changes in the extremities before, during, and after use of these prosthetics.
    3. How does the flexion and extension change the design?
    4. Have you printed the Cyborg Beast designs I’ve uploaded?  What are your thoughts?

Thanks for reading and helping!  Comments appreciated!

Default Series Title

Measurements of a pen

Posted on by
Pilot G2 Gel Pen

Pilot G2 Gel Pen

Pictured are:

  1. The pen end and handle. 9.89mm in outer diameter. 8.06mm in inner diameter. 76.92mm in length, when the button is totally recessed.
  2. The pen front. 68.00mm in length. 8.25 in outer diameter at the middle. 7.91 in outer diameter at the screw threads. 6.35mm in inner diameter.
  3. The spring. It is 19.67mm tall, uncompressed. 6.36mm, compressed. 5.53mm in outer diameter, 4.54mm in inner diameter. The wire is 0.47mm in diameter.
  4. The rubber grip. 1.3mm thick. 8.41mm inner diameter. 37.77mm in length.
  5. The ink cartridge. It is 6.03mm in diameter. 110.47mm in length.  Filled with ink.

Why am I telling you these things?  Stay tuned…