Back to: [Hand Devices](wiki:/s/e-nable-devices/wiki/Hand+devices#null "Hand devices") --- # 1. Basic Info  **Author:** Mat Bowtell (Free 3D Hands) **Device type:** Hand **Minimum user needs:** A functioning wrist and enough palm to push against the device's hand socket MARKER **Type of device:** Mechanical | Maturity | Cost of Materials | Popularity | Assembly difficulty | Grip Strength | | --- | --- | --- | --- | --- | |  |  |  |  |  | To learn about what each of the above icons represents, please refer to the [Device Ratings Guide](wiki:/s/chapter-spotlight/wiki/Project+Ideas+%26+Suggestions#null "Project Ideas & Suggestions"). **Development status:** Mostly finished **Basic data** - Number of parts: 🔴 - Assembly time (estimated): 🔴 - Store-bought parts: velcro straps - Number of known builds: 🔴 - Grip type: 🔴 - Actuation type: Wrist powered device, wires for closing, joint elasticity for opening - Scalability: 50-100% of the STL file size, only in the Slicer **Basic description** One of the fancier looking designs from our collection, this design features completely silent hinges and a sculpted aesthetics to make it more bio mimetic. **License:** Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) **Credit and Contributions:** missing credit --- # 2. Links **Main STL Files:** https://www.thingiverse.com/thing:4618922 **Major Modifications:** 🔴 You can request a modification in the comments below **Source Files:** original Blender file is available with the STLs. (before all the cutouts for the joint) **Instructionals:** An instructional document is available with the STLs. **Editors and Customizers:** e-NABLE Customizer: https://bymu.eu/customizer/?device=kinetic-hand --- # 3. Makers missing photo of made device 🔴 **Bill of Materials** velcro straps **Tools:** missing tool recommendations 🔴 **Recommended print settings:** Rafts: No Supports: No Resolution: 0.2 Infill: 40% Filament brand: 3D Fillies, Ninjatek Filament color: Multiple Filament material: PLA+/PLA, Ninjaflex **Print time** for 100% scale: 🔴 **Weight** for 100% scale: 🔴 **Device advantages:** Silent Operation The flexible hinges are designed to prevent any contact between rigid parts, allowing for silent operation of the hand. Moulded Silicone Finger Grips Using a scalable 3D printed mould, grippy silicone finger grips allow the fingers to better grip a wide range of objects. This also eliminates the need to use consumer products such as Lee Tippi Micro-Gel finger grips which are hard to source, expensive and limited to only a few sizes. Split Hinges The hinges are designed to fit from one side, and stretch fit from the other. This prevents the hinge from sliding out laterally. Hinges do not require any glue, and provide an ideal amount of elasticity to open the fingers. Dual Tendons The need to tie tendons in the fingers has been eliminated, with tendons looping back through the fingers and hand being tied only once at the tensioner. Flexible Tensioners The tensioners are made from an elastic material to allow individual fingers to come to a close while the other fingers continue to travel. There is no inter-connection between fingers, allowing for even grip distribution on a wide range of different object shapes. Part Numbering All of the finger parts, hinges and grips are individually numbered to assist during assembly, ensuring correct part position and orientation. Allowance for Partial Thumb By optimizing wall thicknesses and tendon routing, we have created additional space inside the Palm cavity to allow for a partial thumb. Flexible Palm Cover The flexible Palm Cover improves comfort for the user, since this is where all of the force is applied during use. It can also stretch to help when inserting the partial hand. Adjustable Tensioner Positions Tensioner positions can be adjusted under the Gauntlet Cover to allow individual finger open and close positions to be incrementally adjusted to suit individual preference. Protective Gauntlet Cover Tensioners and tendon knots are protected by the Gauntlet Cover to improve durability and prevent damage. Improved Scalability The Kinetic Hand has been tested successfully between scales of 50% and 100% of the CAD model, which is designed at the scale of a large adult. We recommend 60% as the minimum scale to use for part strength and ease of assembly. Printing Support Elimination All parts have been designed and oriented to eliminate the need for printing supports which are difficult and time consuming to remove. Smooth Part Surfaces The parts have been oriented to minimize the appearance of 3D print layers, whilst maintaining strength in design. Increased Durability The flexible hinges allow fingers to be bent and twisted to the same degree as a human finger without breaking. Three Directional Scalability Since the Kinetic Hand uses flexible hinges rather than snap pins, it can be scaled in X, Y and Z directions independently without compromising part fitment or function. Eased Fitting Tolerances Regardless of hand scale and size, the flexible hinges are designed to fit tightly with no need for fitting tolerances at different scales. Reduced Closing Angle The Kinetic Hand only requires 18 degrees of wrist movement to allow the fingers to fully close, making it able to be used by people with very limited wrist movement. Multiple Palm Variants To accommodate for various levels of hand difference, we have designed multiple palm variants to suit these conditions. --- # 4. Educational At Free 3D Hands, we have been designing, trialling and improving the Kinetic Hand for almost three years since November 2017. Over that period, we have made continuous incremental improvements to the design based on recipient feedback. The Kinetic Hand is a body powered device, and is designed to be used by people with congenital hand differences, with a functioning wrist to open and close the fingers. The Kinetic Hand design is being released under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) open-source license to encourage further innovation in this field, and improve global access to assistive technology. This design is released for trial and evaluation purposes only, and is intended to benefit certain individuals with specific hand differences and is not intended, and shall not be used, for commercial purposes. The acceptance of this design by Free 3D Hands Ltd, and any such information provided by the design team is presented as is without representation or warranties of any kind, express or implied, and is intended to be a free gift to recipients for the sole purpose of evaluating various design iterations, ideas and modifications. The Kinetic Hand must be used for only light tasks such as picking and placing of small objects, and not for any tasks that could be considered dangerous. Any individual associated with Free 3D Hands Ltd shall not be liable for any injuries or damages resulting from the use of any information or designs provided. The Kinetic Hand is experimental, is not classified as a medical device, and is for evaluation purposes only. In some cases, these devices will not be appropriate for each individual, and consultation with medical professionals and occupational therapists must be sought and obtained before use. The Kinetic Hand has been designed using a virtual clay modelling software called Geomagic Freeform Plus to create an organic shape, and then has been engineered and simulated in Solidworks with support of an add-in called Power Surfacing RE. No historical credits available. https://free3dhands.org/ (owner's link) **Have you created other related educational content or resources?** We'd love to feature your work! Moreover, if you want to contribute, but don't know how, help us learn more about our own devices. The red marks (🔴) are there because we don't have that information yet. If you figure it out, please leave it in the comments of this page, and an admin will put it in the page, and you'll get your name in the Contributions section. Thanks for your help! --- # 5. Engineering  **Actuation data** Wrist up-down movement is transferred to the fingers via wires that go through wire channels above the hand and underneath the artificial fingers. This creates the flexing motion, while the elasticity of the joint pieces ensure the fingers snap back into place. **Joint data** All joints (2 wrist joints + fingers) feature a solid joint piece made of a soft material, that allows the components to bend. Joints: Wrist: 2 (side mounted) Thumb: 1 Fingers: 2 each **Number of finger joints:** 2 **Flexion data:** Wire, secured in the tensioner box, goes through the top of the hand , crosses the knuckles and traverses the underside of the fingers. When the wrist flexes, the distance between the forearm socket and the arm socket increases, which pulls the fingers closed. **Extension data:** The extension is done through the elasticity of the solid joints. **Socket data** Due to the joint design, this device can be scaled independently on all axes. This can be done in the Slicer. More info available in the device's guide, on Thingiverse. **Grips:** 🔴 **Bionic data** N/A **Known issues and solutions** no issues have been reported Do you know of an issue with this device? Do you have a solution for a common issue? 🔴 **Help resources** please ask on the main Hub if you need assistance, or in one of the weekly meetings. **Requested Modifications** no modifications have been requested at this point --- # 6. Lists & Media     **Media links:** no links available 🔴 **Community Contributions:** no community contribution yet **Help needed** 🔴🔴🔴🔴🔴 The red mark (🔴) indicates that we haven't aquired that information yet, and we need your help. If you see such a mark and have the time to figure that data out, please note it down in the comments of this page! An admin will put it as official content as soon as they see it, and you'll get mentioned in the Contributions at the end of the page. Thank you for your help!