1. Introduction

Adopting an open-source model of technological development enables equipment designers to quickly build upon one another’s work [1,2,3]. This democratization of design assists many individuals in effectively working together by making a range of contributions over time using open source tools [4,5,6]. Some of the most effective tools for encouraging widespread open hardware designs are themselves means of digital distributed manufacturing [7,8]. For example, the open source nature of the self-replicating rapid prototyper (RepRap) 3-D printer [9,10,11] has radically increased the accessibility of additive manufacturing (AM) while eviscerating the costs of rapid prototyping and product fabrication [12,13,14,15]. RepRaps and derivative commercial variants have obtained mechanical 3-D printed part strengths [16] and qualities of interest to the scientific community [17]. Many open source digitally fabricated devices are now widely used by the scientific community [18,19,20]. For example, 3-D printed parts are used in chemical mixing [2,20,21,22,23,24], optical and mechanical testing [24,25,26], water quality testing [27,28,29,30], and syringe pumping [31,32,33,34] (which can be in turn used for more complicated systems such as fabricating microfluidics and metafluidics [35,36,37] or slot die deposition [38]). In addition to offering scientists the ability to customize their equipment and fully control their function, open source 3-D printable tools are much less expensive than equivalent or inferior commercial systems [18,39,40]. In general, these economic savings are greater for a high percentage of the components able to be 3-D printed [41]. A high return on investment (ROI) is realized for distributed manufacturing with commercial polymer 3-D printing filament based on downloaded substitution values [42,43]. In order to continue to “stand on the shoulders of giants” in open hardware [44], this paper describes the design of an open source completely 3-D printable centrifuge.

A centrifuge is a machine that holds rapidly rotating containers while applying centrifugal force to the fluids inside the containers to separate them based on different densities. Centrifuges are commonly required devices in medical diagnostics facilities because they are used for determining the concentration of pathogens and parasites in biological fluids, DNA preparation, and the extraction of plasma from the whole blood needed for immunoassays or hematocrit analysis. There are many commercial laboratory centrifuges and a number of open source variants, including the open analytical ultracentrifugation (AUC) [45], the laser cut OpenFuge [46], the Polyfuge [47], several variations of minicentrifuges [48,49,50], and one that uses a Dremel and 3-D printed chuck [51]. These open hardware tools do provide for those without access to more expensive proprietary tools [52], but they all depend on access to electricity. Unfortunately, an estimated 1.1 billion people (e.g., 14% of the global population) do not have access to electricity [53]. In addition, even many of those that do have access to electricity have unreliable power. For example, in Nigeria, power outages over extended times have forced a shift to expensive and polluting captive power generation in the majority of businesses [54]. To overcome this challenge of reliable electric power, several open source hand-powered centrifuges have been developed, including the paperfuge [55], a salad spinner centrifuge [56], and an eggbeater centrifuge [57]. All of these are functional, but they lack either large volume capabilities [55] or reliability. To overcome this, several companies have commercialized relatively robust hand-crank centrifuges, which cost U.S. $60–100 [58,59]. These costs can still be prohibitive, and as centrifugation is the first key step in most diagnostic assays [60], there is a need for a low-cost, portable, human-powered centrifuge that can be used by scientists and medical personnel, especially for diagnostics in resource-limited environments [60,61,62,63].

This study provides the designs for a low-cost 100% 3-D printed centrifuge apparatus, which can be fabricated on any low-cost RepRap-class fused filament fabrication (FFF)- or fused particle fabrication (FPF)-based 3-D printer. In addition, a validation procedure for quantifying the rotational speed is provided, which makes use of a smart phone or web camera. The design was fabricated and tested, and the results are discussed in the context of resource-constrained medical and scientific facilities.

2. Materials and Methods

2.1. Design

The design goal for this apparatus was to provide 1200 rotations per minute (rpm), with a handle rotational speed of the operator (N₁) of 120 rpm (i.e., 2 rotations in 1 s). This centrifuge apparatus uses one set of spur gears and one set of bevel gears to achieve the desired gear ratio. Figure 1 shows the design of the gearing system.

2.1.1. Gear Designing and Final Drive Calculations

Considering the rotational speed of the handle by the operator, N₁ to be 120 rpm, the rotational speed for the 2nd spur gear, N₂, is equal to 480rpm:

N₂= N₁T₁/T₂(1)

• Teeth on 1st spur gear: T₁ = 60;

• Teeth on 2nd spur gear: T₂ = 15;

• Teeth on 1st bevel gear: T₃ = 50;

• Teeth on 2nd bevel gear: T₄ = 20.

N₂ = N₃(2)

N₄= N₃T₃/T₄ = N₂T₃/T₄(3)

Thus, for this apparatus, the number of test tube rotations (r_t) is given by

r_t = Cr_h(4)

RCF = 1.118 × 10⁻⁶ × R [mm] × N₄² [rpm](5)

2.1.2. Operation of Design

• Rotating the handle rotates the bigger spur gear, which starts the motion. The two spur gears in contact have equal modules. The module is the ratio of the reference diameter of the gear to the number of teeth on the gear. The bigger spur gear has 60 teeth and a module of 2. Although a larger spur gear would yield a higher gear ratio, it would also increase the size of the casing and in turn the size of the whole apparatus. A spur gear with 60 teeth and a module of 1.5 modules was chosen, considering the need of the final required rotations of the rotor (N₄). Meshed to the bigger spur gear is a smaller spur gear with an equal module. To mesh and rotate a set of any gears, it is necessary that both the gears should have the same profile and an equivalent module. This smaller spur gear is coupled to a larger bevel gear to eliminate the overhang and also another component required to hold the two together. The bigger bevel gear has 50 teeth and a module of 2. The bevel gear is used to transmit the motion in a perpendicular direction. A smaller bevel gear is then meshed with the large one to increase the rotations per minute of the test tubes.

• High rotational speeds of 1200–2000 rpm are required to carry out typical medical tests. Thus, this gear train is designed in such a way that, with every two rotations per second, the rotor rotates at 1200 rpm. With every 2.5 rotations per second of the handle, the rotor rotates at 1500 rpm, and with 3 rotations per second, it can do 1800 rpm. The commercial equivalent products are capable of rotating at 1800 rpm, which is equal to the rotational capability of this 3-D printed centrifuge apparatus. The speeds can be easily increased if the number of teeth on either of the bevels or spurs or both bigger gears are increased and the source code in FreeCAD (computer-aided design 3-D modeling software, www.freecadweb.org) is made available for those that need this capability.

• The dimensions of the handle are designed in such a way that it will not interfere with the rotation of the test tubes. The grip is designed to keep in mind the ergonomics of the human hand and its motion while rotating the handle. Enough grip is provided on the grip bar, which freely rotates around the centerpiece of the handle. The horizontal motion of grip is constrained by implementing a ball–socket joint at the end of the handle.

• Test tubes are placed in the test rings, which are specifically designed for standard test tubes. However, there is a wide variety of test tubes that are available on the market. All of the part files in FreeCAD are made available and open source so that others can adapt the tube holders to meet other sizes of test tubes. The test rings that hold the test tubes are locked in the rotor by using rotor snaps. These snaps can easily withstand the high centrifugal forces acting on them, as they are tightly fitted in the rotor itself. The rotor diameter is 120 mm, which is enough to generate high centrifugal force, following Equation (4).

2.1.3. Bill of Materials

The bill of materials (BOM) is made up of all 3-D printed components, which are summarized in Table 1.

2.2. Fabrication

The components shown in Table 1 are available on the Open Science Framework [64] and are released under a GNU General Public License (GPL) 3.0 [65]. Parts K and L are borrowed from a creative commons-licensed C-clamp design [66]. All of the parts were 3-D printed with glycol-modified polyethylene terephthalate (PETG) IC3D filament of diameter 2.85 mm on a Lulzbot TAZ 6 (Aleph Objects, Loveland CO). The objects were sliced with Cura Lulzbot edition v.3.6.3 [67] using the standard settings summarized in Table 2.

2.3. Assembly

All of the parts of the centrifuge apparatus are shown in Table 1, from Part A through Part O. The assembly of the open source centrifuge can be accomplished after the printed parts are prepared as follows. Part C is the big spur gear, whose end part (square-shaped) needs to be scraped with a knife or any sharp object before starting the assembly. Make sure to scrape a little material from the four edges on the square-shaped end of Part C to ensure a tight fit between Part C and the handle (Part N). This is an important step, as a tight fit will make rotating the handle easy and effective. All of the holes on Part A and Part B need to be scraped a little to ensure smooth rotations of the respective gears. This problem is created due to non-uniform printing by the FFF printer. The four sockets on Part A are to be scraped as well for perfect fitting of the ball joints of Part B. Carefully remove a small amount of material from all four sockets if the ball joints are not fitting inside the sockets. This operation may require some extra force. Part A and Part B are the two casings, which cover the gear train of the apparatus. Start assembling with Part B, as the gears are meshed inside this part (Figure 2).

Part B has two holes of equal diameter where the gears are placed in order to carry out correct meshing. The right-hand side of Part B has a smaller diameter casing than the left-hand side does. Place Part C, which is the bigger spur gear, through the hole on the right-hand side (the smaller casing side, as seen in Figure 2). Lock the spur gear from the backside with the small connecting pin, which is included in Part C. This will help to constrain the horizontal movement of the spur gear and will keep the shaft in place while rotating.

Now insert Part E through the bigger circle situated on the top of Part B and hold it at the top (Figure 3a). Then insert Part D, which is the part with coupled gears, through the hole on the left side of Part B (Figure 3b).

Attach part H from the backside of Part B in Part E’s hole, which will hold the couple gears in one place and stop them from swiveling abruptly while rotating (Figure 4a). Then place Part F, which is a small ring or clamp, to constrain the vertical motion of Part E (Figure 4b).

Part A is the other half of the casing, which is used to cover the gear train and clamping. Part A and Part B are clamped to each other using four ball–socket joints. Insert Part M through Part E’s square end and fix it to the casing through the three given holes (Figure 5a). This will help the small bevel gear align perfectly in a vertical direction during rotations. Part K and Part L are used to clamp the whole centrifuge body to any even surface. Join both parts after Part K is passed through Part A’s internal threading. Join Part K and Part L using the ball–socket joint (Figure 5b).

Part N, Part O, and Part P are the components of the handle. Lock Part N in the square end of Part C (Figure 6a). Make sure to scrape some material with the help of a knife or any sharp object from Part C’s square end to tightly fit Part C with Part N. If sufficient material is not scraped, then Part C will not fit with Part N, and if it is scraped more, then the handle will fit loosely, which will create a snapping problem while rotating the handle. Part O is the grip (Figure 6b), which is used to rotate the handle. Fix Part O and Part P with the ball–socket joint to fix the grip (Figure 6c).

Part G, Part I, and Part J are the parts of the rotor assembly (Figure 7). Part G is the rotor that will hold the rings (Part I) and the snaps (Part J). Place the rings in the rotor and clamp the rings by placing the snaps into the rotor. This will prevent the rings from falling during the motion due to high centrifugal force.

2.4. Operation

After completing the assembly, clamp the centrifuge apparatus on one side of a table (preferably a rectangular table and not a circular one). Place the test tubes in the test tube rings carefully. It is extremely important to balance the weight of the test tubes equally. Leaving out test tubes or heavily loading one will cause vibrations and will make the whole apparatus unstable while in operation. If only 3 of the test tubes are used for sample testing, make sure to fill the fourth test tube with water or a liquid that is of similar density to that of the sample. This will ensure an equal distribution of weight. Crank the handle, which is equipped with a grip.

2.5. Validation

As the working part of the centrifuge rotates at a speed of up to 2000 rpm, it may be difficult to track its motion, since the majority of regular web cameras operate at a frequency of 25–30 Hz. Thus, as the whole system represents a mechanical transmission with the fixed gear ratio, an indirect method was chosen to calculate the angular velocity of the tubes based on the speed of rotation of the centrifuge handle (Figure 8).

A Python-based software was developed to automatically measure the rotational speed of the centrifuge. The OpenCV library [68] was used for segmentation and tracking a visual marker located on the centrifuge handle, and the PyQt library [69] was used for creating an open source guided graphical user interface (GUI) application (Figure 9) [70].

The developed application allows users to crop an arbitrary region of interest of the captured camera frame and set red, green and blue (RGB) thresholds for tracking the visual markers of any distinctive colors. It counts the number of centrifuge handle revolutions and calculates the angular velocity of the tubes. With the given information about the tube length, the program also computes its relative centrifugal force. In the case of normal manual rotation, the central marker will be periodically covered by the hand/arm of the user, so it is possible to set the x and y coordinates of the origin point in the program code.

The main computer vision algorithm is provided below. The rpm and RCF calculations are based on tracking the coordinates of the traveler marker located on the centrifuge handle. By applying the specified color thresholds and morphological operations of “opening” and “closing” to a cropped camera frame, the user can mask the marker as a single separated color region. To find the coordinates of its centroid, the method of moments is employed, which allows the centrifuge handle orientation relative to the center of rotation to be calculated. To do this, $RP{M}_T$, the rotational velocity of the tubes in rpm, is given by

(6)${\mathrm{RPM}}_{\mathrm{T}}=\mathrm{G}\cdot \frac{60}{\mathsf{\Delta }\mathrm{t}}$

(7)$\mathrm{RCF}=1.118\cdot {10}^{-6}\cdot \mathrm{D}\cdot {\mathrm{RPM}}_{\mathrm{T}}^2$

As can be seen in Figure 9, the user can set the RGB thresholds and crop the region of interest in the video. Users can also set the tube length and gear ratio to calculate the rpm and RCF. The RCF and rotational velocity are plotted in real time. The pseudo-code is given as follows:

2.6. Economic Analysis

In order to determine the costs of the apparatus, the entire device was massed on a digital scale +/−0.01 kg. The total cost (T_c) of the apparatus can be determined by

(8)$\mathrm{Tc}=\mathrm{mCe}+\mathrm{mCp}$

3. Results

All of the parts of the open source centrifuge can be printed on a standard RepRap-class FFF-based 3-D printer. Here, all of the parts were printed on a Lulzbot Taz 6 using standard print settings in PETG. Part A and Part B are the longest prints, and take more than 8 h to complete each. All of the gears are printed with more than 60% fill, and thus they have printing times of more than three hours. The total printing time for all of the parts is about 35 h. The printing time can be reduced if the “high speed” (0.28 mm z height) predefined setting is used with a reduction in the infill percentage up to a certain level. In addition, a nozzle with a larger orifice would also speed up printing.

The open source centrifuge takes about 30 min to assemble after printing all of the parts if all the instructions in Section 2.3 are carefully followed. The open source centrifuge is shown fully assembled in a pre-spin state clamped to a desk in Figure 10. The complete system with filled test tubes is shown during rotation in Figure 11a, and a screen capture of a centrifuge cam used for the GUI is shown in Figure 11b. Note the blue tape on the handle end to enable easy computer vision analysis. The same functionality can be obtained using a different colored 3-D print for Part P, coloring it with a marker, or using a sticker. To see the device in operation, see Supplementary Materials, Video S1: MOST_CENTRIFUGE_VIDEO.avi.

During validation experiments with filled test tubes, the RCF(rpm) function was obtained for a wide range of rotational velocities and compared to theoretical Equation (5) for the test tubes with a length of 100 mm and a total radius of rotation D = 150 mm (Figure 12). The goal of the validation was to confirm that there was no time delay in the computer program between calculating the rotational velocity and the relative centrifugal force. As can be seen in Figure 12, the apparatus performed as expected from a start at stationary to over 1750 rpm. This verified the real-time plot (Figure 9), which displayed a proper RCF/rpm ratio over time and over the full range of rotational velocities. In locations without access to a camera, smart phone, and computer during use, crude estimates could be determined by hand calculations of the same equations using a stopwatch and hand rotation counting to determine the RCF.

4. Discussion

This study successfully described, tested, and validated a completely open source centrifuge, which can be fabricated using only open source tools, validated with a laptop computer with a webcam using only free and open source software, and operated anywhere in the world with no electricity inputs. In addition, this device can be fabricated for far less than commercial proprietary tools. The total mass of the apparatus is 0.550 kg, which results in about U.S. $0.50 in electricity costs and $24.75 in commercial costs of filament, for a total cost of U.S. $25.26. Parts M and N both require printing with support and the use of 2 and 11 g, respectively. This adds about 60 U.S. cents to the total cost (U.S. $25.88). This compares to commercial systems, which cost U.S. $60–100 [59,60] and do not have a means of easy field validation without the use of the open source GUI disclosed here. Thus, a considerable savings of a 57–75% decrease in cost can be achieved with this device. However, as this device is primarily developed for applications in resource-constrained settings, further cost reductions are needed.

The economics of using commercial 3-D printing filament are somewhat attractive: However, they can be improved by using filament fabricated with a recyclebot [73,74,75] from recycled waste polymers. Former 3-D printed polymers can be recycled with acceptable mechanical strengths for about five cycles [76,77]. Thermopolymers, which have already been demonstrated with recyclebot processing, include polylactic acid (PLA) [75,76,77,78,79], PET and PETG [80,81,82], high-density polyethylene (HDPE) [74,82,83,84,85,86,87], acrylonitrile butadiene styrene (ABS) [82,86,87,88,89,90], polystyrene (PS) [82], polypropylene (PP) [82], elastomers [91], as well as polypropylene blends [92] and composites such as waste wood biopolymers [93] and carbon fiber-reinforced plastics [94]). Modern recyclebots can produce filament from waste plastic for electricity costs between 2.4 [90] and 3.6 [75] cents/kg. As the design here was massed at 0.550 kg, it would cost between 1.3 and 2 cents in recycled filament and about 91 cents to print, which results in a total cost of about U.S. $0.92–$0.93. This provides savings of 98%–99% compared to commercial offerings. It should be pointed out here that these costs do not include any labor costs for either the collecting, sorting, or processing (shredding) of the waste plastic to feedstock for the recyclebot. Commercial recycled plastic granules are available from U.S. $1.00–3.00/kg. Purchasing relatively expensive commercial recycled plastic would still result in a centrifuge cost of only a dollar or two. However, there are two ways these costs can be even further reduced from the sub-dollar costs associated with distributed recycling with a recyclebot system. The first involves using a previously acquired solar photovoltaic-powered recyclebot [78,87,89] and a solar-powered 3-D printer [87,89,95,96,97]. The electricity costs are then avoided, dropping the marginal costs of materials and energy near to zero, although the capital cost would need to be amortized by printing many valuable products or be given as a donation. In addition, direct fused particle fabrication (FPF) or fused granular fabrication (FGF) can be used to recycle a wide range of materials, including PET, PP, ABS, and PLA [98]. Directly printing (material extrusion) shredded waste plastic and avoiding filament manufacturing takes the cost of the materials and processing of the open source centrifuge down under U.S. $0.50. The commercial open source FPF/FGF systems have high capital costs, although they can fabricate generally large, valuable products that provide users with a high return on investment if they are used frequently [99]. Future work is needed to make a desktop scale particle material extrusion 3-D printer and apply it to manufacturing of this device.

This study indicates several areas of future work. First, more research is needed to make small-scale FPF/FGF 3-D printers to fabricate waste plastic into open source centrifuges for resource-constrained areas. Such systems would ideally be solar photovoltaic-powered. Future work could also look at the potential for a 3-D printable waste plastic shredder, again ideally solar or manual powered, that could be used to complete the entire tool chain from waste to finished scientific instrument. It should be noted that in the cost calculations above, labor costs were not included. Future work can address the labor costs in a range of contexts: However, a past analysis of open hardware for science by Trivedi et al. [23] has shown that zero labor costs are relevant to several scientific instrument situations where (i) there is no opportunity cost to using existing salaried employees (e.g., lab managers, research assistants, teaching assistants, or other positions that are paid as a fixed cost and for which there is no opportunity cost of work on the fabrication of the device); (ii) fabrication of the instruments is used as a learning aid [100,101]; or (iii) the labor is provided by unpaid interns or volunteers (e.g., undergraduate students volunteering for research experience). In general, in resource-constrained settings, as well as in most academic institutions, these conditions can be met. For those settings where this is not the case, tasks to order and deploy a commercial product should be compared to the relatively low time investment of printing (only set-up and take-off is necessary, as the 3-D printers can be left unattended) and assembling the open source centrifuge.

5. Conclusions

This paper provides complete open source plans, including a BOM, instructions for fabrication and operation, and open source software for a hand-powered centrifuge. This study successfully described, tested, and validated this completely open source centrifuge, which can be fabricated using only open source tools (e.g., a RepRap-class 3-D printer). Further, the validation itself used only open source and readily available tools of a computer with a webcam. The instrument can be operated anywhere in the world with no electricity inputs, obtaining a radial velocity of over 1750 rpm and over 50 N of relative centrifugal force. Using commercial filament, the instrument costs about U.S. $25, which is less than half of all commercially available systems. However, the costs can be dropped further using recycled plastics in open source systems for over 99% savings.

Supplementary Materials

The following are available online at https://www.mdpi.com/2410-390X/3/2/30/s1. Video S1: MOST_CENTRIFUGE_VIDEO.avi.

Author Contributions

Conceptualization, J.M.P.; data curation, A.L.P.; formal analysis, S.S.S., A.L.P., and J.M.P.; funding acquisition, J.M.P.; investigation, S.S.S. and A.L.P.; methodology, S.S.S., A.L.P., and J.M.P.; resources, J.M.P.; software, A.L.P.; supervision, J.M.P.; validation, A.L.P.; visualization, S.S.S. and A.L.P.; writing—original draft, S.S.S., A.L.P., and J.M.P.; writing—review and editing, S.S.S., A.L.P., and J.M.P.

Funding

This research was funded by Aleph Objects and the Richard Witte Endowment.

Acknowledgments

The authors would like to thank Shaunak P. Mhatre for technical assistance.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

Figures and Tables

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Figure 1. Schematic of gear design.

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Figure 2. Assembling Parts B and C.

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Figure 3. (a) Inserting Part E into Part B and (b) inserting Part D.

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Figure 4. (a) Attaching Part H and (b) Part E.

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Figure 5. (a) Inserting part M and (b) assembling Parts K and (c) L.

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Figure 6. (a) Attaching handle N, and the (b) grip and (c) lock.

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Figure 7. Assembling (a) Part G, (b) Part I, and (c) Part J.

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Figure 8. Image-based markers segmentation. (a) Cropped frame of the centrifuge with the visual markers; (b) masked image; (c) calculated handle orientation.

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Figure 9. A screenshot of the open source biomedical centrifuge interface for camera-based rpm and relative centrifugal force calculations.

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Figure 10. Fully assembled open source centrifuge in a pre-spin state.

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Figure 11. (a) Complete system with filled test tubes during rotation and (b) a screen capture of a centrifuge cam used for the graphical user interface (GUI). Tracking of the handle marker, time, angle, number of revolutions, rpm, and RCF are all shown in real time.

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Figure 12. Relative centrifugal force as a function of the rotational velocity of the centrifuge test tubes with a length of 100 mm and a total radius of rotation D = 150 mm (Equation (7)).

Bill of materials for the 3-D printed open source centrifuge.

Slicer settings for each 3-D printed part.