Category: Software

General-purpose computers doing something specific

Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Improved Motor Reaction Spacer

The original BBS02 reaction spacer for Gee’s Terry Symmetry didn’t work quite the way I expected:

Bafang BBS02 - reaction block displacement
Bafang BBS02 – reaction block displacement

The motor evidently vibrates enough to propel the block forward, shearing the double-sticky foam tape which was never intended to resist force in that plane. I thought the block was located at the point where the motor casing was tangent to the frame tube, so as to equalize the forces in both directions, but … nope.

A revised design based on measurements informed by new knowledge:

Terry - Bafang motor spacer - improved - solid model
Terry – Bafang motor spacer – improved – solid model

The upper curve is now symmetric and the whole block mounts more rearward under the bottom bracket lug, where some tedious work with a machinists square located the real tangent point:

Bafang BBS02 - reaction block improvement
Bafang BBS02 – reaction block improvement

The motor sure doesn’t look like it’s tangent, but a dry fit showed all the curves laid against the case and tubes.

The brazing fillet means the step fitting the downtube can’t sit snug against the edge of the lug, but most of the reaction force should go through the section into the lug, near the center of the block.

A crude marker will keep track of any motion:

Bafang BBS02 - reaction block marker
Bafang BBS02 – reaction block marker

I think the symmetric curve against the motor has enough projection to keep the block from wandering off, even if I haven’t gotten the location exactly right.

Stipulated: Hope is not a strategy.

The OpenSCAD source code:

MotorOD = 111;              // motor frame dia
MotorOffset = 10.0;         // motor OD tangent wrt lug edge
ShiftSpace = 6.0;           // motor to frame space

LugLength = 25.0;           // length of section over BB lug

Spacer = [5.0 + LugLength,DownTube[ID]/2,4*ShiftSpace];
SpaceAngle = 0*atan(1.8/Spacer.x);            // tilt due to non-right-angle meeting
echo(str("Spacer angle: ",SpaceAngle));

module MotorSpacer() {

    difference() {
        translate([LugLength - Spacer.x/2,0,0])
           cube(Spacer,center=true);
        translate([0,0,DownTube[ID]/2])
            rotate([0,90 + SpaceAngle,0]) rotate(180/FrameSides)
                cylinder(d=DownTube[ID],h=DownTube[LENGTH],$fn=FrameSides,center=true);
        translate([DownTube[LENGTH]/2,0,DownTube[ID]/2 - DownTube[LENGTH]*sin(SpaceAngle)/2])       // concentric with ID
            rotate([0,90 + SpaceAngle,0]) rotate(180/FrameSides)
                cylinder(d=DownTube[OD],h=DownTube[LENGTH],$fn=FrameSides,center=true);
        translate([MotorOffset,0,-(MotorOD/2 + ShiftSpace)])
            rotate([90,0,0]) rotate(180/48)
                cylinder(d=MotorOD,h=2*Spacer.y,$fn=48,center=true);
    }

}

Nothing like actual riding to reveal what needs more thought!

Electronics Workbench, Machine Shop, Recumbent Bicycling, Software

Tour Easy: Amber Running Light

Having seen a few bikes with amber “headlights” and being desirous of reducing the number of batteries on Mary’s bike, this seems like an obvious first step:

Fairing Mounted Side Marker - First Light
Fairing Mounted Side Marker – First Light

It descends from the fairing flashlight mount with an entry to suit a 15 mm truck side marker body:

LightBodies = [
  ["AnkerLC90",26.6,48.0],
  ["AnkerLC40",26.6,55.0],
  ["J5TactV2",25.0,30.0],
  ["InnovaX5",22.0,55.0],
  ["Sidemarker",15.0,20.0],
  ["Laser",10.0,30.0],
];

The rest of the code gets a few cleanups you’d expect when you compile code untouched for a few years using the latest OpenSCAD.

The markers are allegedly DOT rated, which matters not for my use case: SAEP2PCDOT.

The mount is grossly overqualified for a wide-beam light with little need for aiming:

Fairing Mounted Side Marker - test light
Fairing Mounted Side Marker – test light

Eventually, the marker should slip into a prealigned cylindrical holder, with a dab of epoxy to keep it there.

The lights are a buck apiece, so there’s no reason to form a deep emotional attachment. They are the usual poorly molded and badly assembled crap, although the next step up from a nominally reputable supplier is a factor of five more expensive.

It’s generated for the left side of the fairing, although I think having a pair of them would improve conspicuity:

Fairing Mounted Side Marker - installed
Fairing Mounted Side Marker – installed

Being automotive, it runs from a 12 V supply, which comes from a boost converter driven by the Bafang 6 V headlight output. The absurdity of bucking a 48 V lithium battery to a 6V switched headlight output, then boosting it to 12 V to drive a single amber LED with a 1.5 V forward drop does not escape me.

It’s possible to slice the lens off (using a lathe), remove / replace the resistor, then glue it back together, which would be worthwhile if you were intending to drive it from, say, an Arduino-ish microcontroller to get a unique blink pattern.

Given the overall lack of build quality, it might make more sense to slap a condenser lens in front of a Piranha LED.

Bonus: contrary to what you (well, I) might expect, the black lead is positive and the white lead is negative.

Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Motor Reaction Spacer

The Terry Symmetry’s rear shift cable passes along the side of the downtube and through a plastic guide channel under the bottom bracket shell. The Bafang BBS02 motor must press against the bottom of the downtube, so the shift cable rubs against the top of the motor.

The solution is a small block shaped around the point of contact to cradle the downtube, the bottom bracket shell lug, and the motor case:

Terry - Bafang motor spacer - solid model
Terry – Bafang motor spacer – solid model

A strip of double-sided foam tape holds the block to the motor and the reaction force from the motor’s torque presses the block against the downtube:

Terry Bafang - motor reaction block
Terry Bafang – motor reaction block

Seen from the other side, looking parallel to the shift cable, you can see the tight clearance:

Terry Bafang - shift cable clearance
Terry Bafang – shift cable clearance

The block holds the motor 8 mm from the downtube, just enough to give the cable some breathing room.

The block is slightly taller on its front end, because the motor doesn’t meet the downtube at a right angle:

Terry - Bafang motor spacer - tube angle - solid model
Terry – Bafang motor spacer – tube angle – solid model

I determined the proper angle by taping waxed paper to the top of the motor, sticking a trial (non-angled) block to the downtube, coating its bottom surface with hot-melt glue, then squishing the motor against the block. The cooled glue was flush with the block on the rear and 1.8 mm thick on the front, a 5° angle over the 20 mm block.

Definitely easier than correctly figuring the geometry from first principles: tweak the model to include the measured thickness, compute the angle, tilt the tube, and print another block that fits like it grew there.

With the block in place and the motor held against the downtube, tighten the retaining nut against the “fixing plate” by giving it a few gentle whacks with a hammer, then tighten the jam nut.

The OpenSCAD source code snippet:

// Motor Reaction Block
// Holds motor away from downtube enough to miss rear shift wire

MotorOD = 111;              // motor frame dia
MotorMountRad = 85;         // BB spindle center to motor center
Space = 8.0;                // motor to frame space

Spacer = [20.0,DownTube[ID]/2,4*Space];
SpaceAngle = atan(1.8/Spacer.x);            // tilt due to non-right-angle meeting
echo(str("Spacer angle: ",SpaceAngle));

module MotorSpacer() {

    difference() {
        cube(Spacer,center=true);
        translate([0,0,DownTube[ID]/2])
            rotate([0,90 + SpaceAngle,0]) rotate(180/FrameSides)
                cylinder(d=DownTube[ID],h=DownTube[LENGTH],$fn=FrameSides,center=true);
        translate([DownTube[LENGTH]/2,0,DownTube[ID]/2 - DownTube[LENGTH]*sin(SpaceAngle)/2])       // concentric with ID
            rotate([0,90 + SpaceAngle,0]) rotate(180/FrameSides)
                cylinder(d=DownTube[OD],h=DownTube[LENGTH],$fn=FrameSides,center=true);
        translate([0,0,-(MotorOD/2 + Space)])
            rotate([90,0,0]) rotate(180/48)
                cylinder(d=MotorOD,h=2*Spacer.y,$fn=48,center=true);
    }

}

Mary’s Tour Easy didn’t need this block, because all the cables run elsewhere, but I did capture a piece of closed-cell foam between its vestigial downtube and the motor to prevent chafing.

Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Terry Symmetry Battery Mount

The Bafang 48 V 11.6 A·h battery for Gee’s Terry Symmetry mounts on the downtube:

Bafang BBS02 - Terry Symmetry full assembly
Bafang BBS02 – Terry Symmetry full assembly

The battery slides onto a plate screwed to the pair of water bottle studs brazed to the tube:

Terry Bafang battery mount plate - test install
Terry Bafang battery mount plate – test install

Water bottle studs are (nominally) 65 mm on center. One stud normally appears under the plate’s center hole, with the other stud under either the upper or lower slot, depending on whether the battery fits better mounted lower or higher on the downtube.

However, the Symmetry’s downtube is so short the plate must mount with the lowest slot matching the uppermost stud, putting the lower stud beneath the metal compartment with its complete lack of mounting holes.

Well, I can fix that:

Terry Bafang battery mount - internal modifications
Terry Bafang battery mount – internal modifications

The upper hole in the metal base is 65 mm from the middle of the lower slot in the plastic baseplate, which will be (approximately) centered on the upper stud inside the black plastic mount. The location of that hole is not a free variable: it requires measuring and marking from the slot with the battery plate assembled.

The lower hole in the base puts the bottom of its plastic mount just about even with the end of the plate.

I shortened the battery side of the cable, crimped on (genuine!) 45 A Powerpole pins, and shaped the wiring to put the connector inside the metal compartment, out of harm’s way, and shielded from the weather.

The small bar of white HDPE serves as a cable clamp, held by a pair of M3 BHCS in the conveniently tapped holes.

With all that settled, the final iteration of the 3D printed mounting blocks took shape:

Terry - Bafang battery - all stations - solid model
Terry – Bafang battery – all stations – solid model

A station number from 1 through 4 identifies the blocks (station 0 is the blank block shape) and, of course, they’re all different. I refactored the OpenSCAD code used for Mary’s Tour Easy to put the feature selection into vectors, rather than convoluted logic:

Latches = [false,true,true,false,false];                // clearance for battery latch clips
Notch = [false,true,true,false,false];                  // notch for battery screw pockets
Recess = ["None","TeeNut","Bottle","Bottle","TeeNut"];  // stud or nut clearance against frame

HarnessCable = [false,true,true,true,true];             // passage for main harness cable

ShiftWire = [false,true,true,true,true];                //  .. shifter wire through sensor
Ferrules = ["None","Both","Front","None","Back"];       // ferrule and bushing ssockets

GearCable = [false,false,true,true,true];               //  .. gear sensor cable

Producing the features for a specific block is now a straightforward series of obvious choices. For example, adding the channels to clear the battery latches at stations 1 and 2 looks like this:

        if (Latches[BlkNum])
            for (i=[-1,1])
                translate([0,i*LatchOC/2,BlockMaxZ - LatchThick/2 + Protrusion])
                    cube([BossSlotOAL,LatchWidth,LatchThick + Protrusion],center=true);

Both parts of the block show the station number to avoid mixups:

Terry - Bafang battery - station 2 - solid model
Terry – Bafang battery – station 2 – solid model

Each block requires a bit under three hours of printing time, so they’re produced singly:

Terry - Bafang battery - station 2 build - solid model
Terry – Bafang battery – station 2 build – solid model

Building them sideways produces the best surface finish in all the recesses and holes. Small support structures under the rounded corners make them look Good Enough™ for their purpose.

A test assembly:

Terry Bafang battery mount - trial installation
Terry Bafang battery mount – trial installation

The two middle blocks (stations 3 and 2) sit at the water bottle studs. The rightmost block (station 1) is 130 mm from station 2, with the Bafang gear sensor on the rear derailleur cable.

An aluminum plate spreads the clamping force from the M4 screws across the bottom, as seen here below the cable stop cap holding the harness cable:

Terry Bafang - shift stop cap
Terry Bafang – shift stop cap

Those 50 mm screws are too long; a soon-to-arrive bag of 45 mm screws should fit perfectly. The final assembly will use nyloc nuts so they won’t vibrate loose.

The OpenSCAD source code for all the pieces as a GitHub Gist:

// Terry Symmetry - Bafang e-bike conversion
// Ed Nisley KE4ZNU 2021-06
Layout = "BuildClip"; // [Frame,Block,AllBlocks,BuildBlock,DispMount,BrakeMagnet,ShiftCap,BuildShiftCap,Case,NutMold,HeadClip, BuildClip]
Station = 4; // [0:4]
Support = false;
//- Extrusion parameters must match reality!
/* [Hidden] */
ThreadThick = 0.25;
ThreadWidth = 0.40;
HoleWindage = 0.2;
Protrusion = 0.1; // make holes end cleanly
inch = 25.4;
function IntegerMultiple(Size,Unit) = Unit * ceil(Size / Unit);
ID = 0;
OD = 1;
LENGTH = 2;
//----------
// Dimensions
// Bike frame lies along X axis, rear to +X
FrameTube = [400,28.9 + HoleWindage,28.9 + HoleWindage]; // X = longer than anything else
FrameSides = 24;
SpeedOD = 3.5; // speed sensor cable
PowerOD = 6.7; // power cable
Harness = [6.0,13.0,30.0]; // main motor-to-handlebar cable
GearOD = 3.0; // gear sensor cable
HandlebarMax = 1*inch; // middle handlebar diameter
HandlebarMin = 24.0; // .. tape section
HeadTube = [32.0,35.0,8.0]; // ID=tube OD=lug LENGTH=clear between lugs
BottleStud = [5.0,10.0,IntegerMultiple(1.2,ThreadThick)]; // frame fitting for bottle screws
BafangClampID = 22.3; // their handlebar clamp diameter
ShiftOD = 2.0; // rear shifter cable
ShiftFerrule = [ShiftOD,6.0,10.0];
ShiftOffset = 7.5; // .. from downtube
ShiftAngle = -20; // .. from midline
BatteryBoss = [5.5,16.0,2.5]; // battery mount boss, center boss is round
BossSlotOAL = 32.0; // .. end bosses are elongated
BossOC = 65.0; // .. along length of mount
LatchWidth = 10.0; // battery latches to mount plate
LatchThick = 1.5;
LatchOC = 56.0;
// Per-block features
// first element is unadorned block
Latches = [false,true,true,false,false]; // clearance for battery latch clips
Notch = [false,true,true,false,false]; // notch for battery screw pockets
Recess = ["None","TeeNut","Bottle","Bottle","TeeNut"]; // stud or nut clearance against frame
HarnessCable = [false,true,true,true,true]; // passage for main harness cable
ShiftWire = [false,true,true,true,true]; // .. shifter wire through sensor
Ferrules = ["None","Both","Front","None","Back"]; // ferrule and bushing ssockets
GearCable = [false,false,true,true,true]; // .. gear sensor cable
// M3 SHCS nyloc nut
Screw3 = [3.0,5.5,35.0]; // OD, LENGTH = head
Washer3 = [3.7,7.0,0.7];
Nut3 = [3.0,6.0,4.0];
// M4 SHCS nyloc nut
Screw4 = [4.0,7.0,4.0]; // OD, LENGTH = head
Washer4 = [4.2,8.9,1.0];
Nut4 = [4.0,7.8,5.0];
// M5 SHCS nyloc nut
Screw5 = [5.0,8.5,5.0]; // OD, LENGTH = head
Washer5 = [5.5,10.1,1.0];
Nut5 = [5.0,9.0,5.0];
Teenut5 = [6.5,17.0,8.0,2.0]; // OD, LENGTH+1 = flange
// 10-32 Philips nyloc nut
Screw10 = [5.2,9.8,3.6]; // OD, LENGTH = head
Washer10 = [5.5,11.0,1.0];
Nut10 = [5.2,10.7,6.2];
CableTie = [150,5.0,2.0];
WallThick = 4.0; // thinnest wall
BlockMinZ = -(FrameTube.z/2 + WallThick);
BlockMaxZ = FrameTube.z/2 + max(WallThick,Teenut5[LENGTH]) + BatteryBoss[LENGTH];
Block = [25.0,78.0,BlockMaxZ - BlockMinZ]; // Y = battery width
echo(str("Block: ",Block));
Kerf = 0.5; // cut through middle to apply compression
CornerRadius = 5.0;
EmbossDepth = 2*ThreadThick; // lettering depth
//----------------------
// Useful routines
module PolyCyl(Dia,Height,ForceSides=0) { // based on nophead's polyholes
Sides = (ForceSides != 0) ? ForceSides : (ceil(Dia) + 2);
FixDia = Dia / cos(180/Sides);
cylinder(d=(FixDia + HoleWindage),h=Height,$fn=Sides);
}
// frame downtube
module Frame() {
rotate([0,90,0]) rotate(180/FrameSides)
cylinder(d=FrameTube.z,h=FrameTube.x,center=true,$fn=FrameSides);
}
// clamp overall shape
module ClampBlock(BlkNum = 1) {
Screw = Screw4;
Washer = Washer4;
Nut = Nut4;
ScrewOC = LatchOC;
ScrewSides = 8;
ScrewOrient = 180/ScrewSides;
ScrewRecess = LatchThick + Screw[LENGTH] + Washer[LENGTH] + 1.0;
echo(str("Screw length: ",Block.z - ScrewRecess));
difference() {
hull()
for (i=[-1,1], j=[-1,1])
translate([i*(Block.x/2 - CornerRadius),j*(Block.y/2 - CornerRadius),BlockMinZ])
cylinder(r=CornerRadius,h=Block.z,$fn=4*3);
cube([2*Block.x,2*Block.y,Kerf],center=true);
Frame();
for (j=[-1,1]) {
translate([0,j*ScrewOC/2,BlockMinZ - Protrusion])
rotate(ScrewOrient)
PolyCyl(Screw[ID],2*Block.z,ScrewSides);
translate([0,j*ScrewOC/2,BlockMaxZ - ScrewRecess])
rotate(ScrewOrient)
PolyCyl(Washer[OD],BlockMaxZ,ScrewSides);
}
if (Latches[BlkNum])
for (i=[-1,1])
translate([0,i*LatchOC/2,BlockMaxZ - LatchThick/2 + Protrusion])
cube([BossSlotOAL,LatchWidth,LatchThick + Protrusion],center=true);
if (Notch[BlkNum])
translate([0,0,BlockMaxZ - BatteryBoss[LENGTH]/2 + Protrusion])
cube([BossSlotOAL,BatteryBoss[OD],BatteryBoss[LENGTH] + Protrusion],center=true);
if (HarnessCable[BlkNum])
rotate([-155,0,0]) {
translate([0,FrameTube.y/2 - Harness[ID]/2,0])
cube([2*Block.x,2*Harness[ID],Harness[ID]],center=true);
translate([0,FrameTube.y/2 + Harness[ID]/2,0])
rotate([0,90,0])
translate([0,0,-Block.x])
rotate(180/6)
PolyCyl(Harness[ID],2*Block.x,6);
}
if (GearCable[BlkNum])
rotate([-45,0,0]) {
translate([0,FrameTube.y/2 - GearOD/2,0])
cube([2*Block.x,2*GearOD,GearOD],center=true);
translate([0,FrameTube.y/2 + GearOD/2,0])
rotate([0,90,0])
translate([0,0,-Block.x])
rotate(180/6)
PolyCyl(GearOD,2*Block.x,6);
}
rotate([ShiftAngle,0,0]) {
if (ShiftWire[BlkNum])
translate([-Block.x,FrameTube.y/2 + ShiftOffset,0])
rotate([0,90,0]) rotate(-(90 + ShiftAngle))
PolyCyl(ShiftOD,2*Block.x,6);
if (Ferrules[BlkNum] == "Back" || Ferrules[BlkNum] == "Both") {
i = 1;
translate([i*(Block.x/2 - ShiftFerrule[LENGTH]),FrameTube.y/2 + ShiftOffset,0])
rotate([0,i*90,0]) rotate(-i*(90 + ShiftAngle))
PolyCyl(ShiftFerrule[OD],Block.x,6);
}
if (Ferrules[BlkNum] == "Front" || Ferrules[BlkNum] == "Both") {
i = -1;
translate([i*(Block.x/2 - ShiftFerrule[LENGTH]),FrameTube.y/2 + ShiftOffset,0])
rotate([0,i*90,0]) rotate(-i*(90 + ShiftAngle))
PolyCyl(ShiftFerrule[OD],Block.x,6);
}
}
if (Recess[BlkNum] == "Bottle") {
rotate(ScrewOrient) {
PolyCyl(BottleStud[ID],2*Block.z,ScrewSides);
PolyCyl(BottleStud[OD],FrameTube.z/2 + BottleStud[LENGTH],ScrewSides);
}
}
else if (Recess[BlkNum] == "TeeNut") {
rotate(ScrewOrient) {
PolyCyl(Teenut5[ID],2*Block.z,ScrewSides);
PolyCyl(Teenut5[OD],FrameTube.z/2 + Teenut5[LENGTH+1],ScrewSides);
}
}
translate([0,15,BlockMaxZ - EmbossDepth/2 + Protrusion])
cube([9.0,8,EmbossDepth],center=true);
translate([0,17,BlockMinZ + EmbossDepth/2 - Protrusion])
cube([9.0,8,EmbossDepth],center=true);
translate([0,-5,BlockMinZ + EmbossDepth/2 - Protrusion])
cube([9.0,30,EmbossDepth],center=true);
}
translate([0,15,BlockMaxZ - EmbossDepth])
linear_extrude(height=EmbossDepth)
rotate(90)
text(text=str(BlkNum),size=5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
translate([0,17,BlockMinZ])
linear_extrude(height=EmbossDepth)
rotate(-90) mirror([0,1,0])
text(text=str(BlkNum),size=4.5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
translate([0,-5,BlockMinZ])
linear_extrude(height=EmbossDepth)
rotate(-90) mirror([0,1,0])
text(text="KE4ZNU",size=4.5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
}
// complete clamp block
module Clamp(BlkNum = 1) {
ClampBlock(BlkNum);
if (Support)
color("Yellow") {
NumRibs = 7;
RibOC = Block.x/(NumRibs - 1);
intersection() {
translate([0,0,BlockMaxZ + Kerf/2])
cube([2*Block.x,2*Block.y,Block.z],center=true);
union() {
translate([0,0,Kerf/2])
cube([1.1*Block.x,FrameTube.y - 2*ThreadThick,4*ThreadThick],center=true);
for (i=[-floor(NumRibs/2):floor(NumRibs/2)])
translate([i*RibOC,0,0])
rotate([0,90,0]) rotate(180/FrameSides)
cylinder(d=FrameTube.z - 2*ThreadThick,h=2*ThreadWidth,$fn=FrameSides,center=true);
/*
translate([0,FrameTube.y/2 + PowerOD/2,Kerf/2])
cube([1.1*Block.x,PowerOD - 2*ThreadWidth,4*ThreadThick],center=true);
for (i=[-floor(NumRibs/2):floor(NumRibs/2)])
translate([i*RibOC,FrameTube.y/2 + PowerOD/2,PowerOD/4])
cube([2*ThreadWidth,PowerOD - 2*ThreadWidth,PowerOD/2 - 2*ThreadThick],center=true);
translate([0,-(FrameTube.y/2 + SpeedOD/2),Kerf/2])
cube([1.1*Block.x,SpeedOD - 2*ThreadWidth,4*ThreadThick],center=true);
for (i=[-floor(NumRibs/2):floor(NumRibs/2)])
translate([i*RibOC,-(FrameTube.y/2 + SpeedOD/2),SpeedOD/4])
cube([2*ThreadWidth,SpeedOD - 2*ThreadWidth,SpeedOD/2 - 2*ThreadThick],center=true);
*/
}
}
}
}
// Half clamp sections for printing
module HalfClamp(BlkNum = 1, Section = "Upper") {
render()
if (Section == "Upper")
intersection() {
translate([0,0,BlockMaxZ/2])
cube([1.1*Block.x,Block.y,BlockMaxZ],center=true);
translate([0,0,-Kerf/2])
Clamp(BlkNum);
}
else
intersection() {
translate([0,0,-BlockMinZ/2])
cube([1.1*Block.x,Block.y,-BlockMinZ],center=true);
translate([0,0,-BlockMinZ])
Clamp(BlkNum);
}
}
// Handlebar mount for controller
module DispMount() {
ClampRing = [HandlebarMax,HandlebarMax + 2*WallThick,10.0];
ClampOffset = (HandlebarMax + BafangClampID)/2 + 6.0;
DispStudLenth = 16.5;
NumSides = 24;
Tilt = 0*atan2((ClampRing[OD] - BafangClampID)/2,ClampOffset);
echo(str("Tilt: ",Tilt));
difference() {
union() {
hull() {
cylinder(d=ClampRing[OD],h=ClampRing[LENGTH],$fn=NumSides);
translate([0,ClampOffset,0])
cylinder(d=BafangClampID,h=ClampRing[LENGTH],$fn=NumSides);
}
translate([0,ClampOffset,0])
cylinder(d=BafangClampID,h=ClampRing[LENGTH] + DispStudLenth,$fn=NumSides);
translate([-ClampRing[ID]/4,-(ClampRing[OD]/2),ClampRing[LENGTH]/2])
rotate([0,90,0]) rotate(180/8)
cylinder(d=ClampRing[LENGTH]/cos(180/8),h=ClampRing[ID]/2,$fn=8);
}
cube([Kerf,4*ClampOffset,4*DispStudLenth],center=true);
translate([0,0,-Protrusion])
cylinder(d=ClampRing[ID],h=ClampRing[LENGTH] + 2*Protrusion,$fn=NumSides);
translate([-ClampRing[ID]/2,-(ClampRing[OD]/2),ClampRing[LENGTH]/2])
rotate([0,90,0]) rotate(180/8)
PolyCyl(Screw3[ID],ClampRing[ID],8);
for (i=[-1,1])
translate([i*ClampRing[ID]/4,-(ClampRing[OD]/2),ClampRing[LENGTH]/2])
rotate([0,i*90,0]) rotate(180/8)
PolyCyl(Washer3[OD],ClampRing[ID],$fn=8);
translate([-5,25,EmbossDepth/2 - Protrusion/2])
rotate(Tilt)
cube([4.5,21.5,EmbossDepth + Protrusion],center=true);
if (false)
translate([-6,25,EmbossDepth/2 - Protrusion/2])
rotate(-Tilt)
cube([4.0,27,EmbossDepth + Protrusion],center=true);
}
translate([-5,25,0])
linear_extrude(height=EmbossDepth)
rotate(90 + Tilt) mirror([0,1,0])
text(text="KE4ZNU",size=3.3,spacing=1.05,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
if (false)
translate([-6,25,0])
linear_extrude(height=EmbossDepth)
rotate(90 - Tilt) mirror([0,1,0])
text(text="softsolder.com",size=2.2,spacing=1.05,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
}
// Mold to reshape speed sensor nut
SensorNut = [0,14.4,13.0];
SensorMold = [SensorNut[OD] + 2*WallThick,SensorNut[OD] + 2*WallThick,SensorNut[LENGTH] + WallThick];
MoldSides = 20;
RodOD = 1.6;
module NutMoldBlock() {
difference() {
translate([0,0,SensorMold.z/2])
cube(SensorMold,center=true);
translate([0,0,WallThick])
rotate(180/MoldSides)
PolyCyl(SensorNut[OD],2*SensorNut[LENGTH],MoldSides);
translate([0,0,-Protrusion])
rotate(180/8)
PolyCyl(SpeedOD,2*SensorMold.z,8);
for (i=[-1,1])
translate([i*(SensorMold.x/2 - WallThick/2),SensorMold.y,SensorMold.z/2])
rotate([90,0,0])
PolyCyl(RodOD,2*SensorMold.y,6);
}
}
module NutMold() {
gap = 1.0;
for (j=[-1,1])
translate([0,j*gap,0])
intersection() {
translate([0,j*SensorMold.y,0])
cube(2*SensorMold,center=true);
NutMoldBlock();
}
}
// Brake sensor magnet mount
// Magnetized through thinnest section
module BrakeMagnet() {
Magnet = [10.5,3.0,5.5];
Plate = 2*ThreadThick;
BrakeRad = 10.0; // brake handle curve Radius
Holder = [2*BrakeRad,7.0,Magnet.z + Plate];
difference() {
intersection() {
translate([0,-BrakeRad,0])
rotate(180/24)
cylinder(r=BrakeRad,h=Holder.z,$fn=24);
translate([0,BrakeRad - Holder.y,Holder.z/2])
cube([2*BrakeRad,2*BrakeRad,Holder.z],center=true);
translate([0,0,-2*BrakeRad/sqrt(2) + Holder.z - 3.0 + BrakeRad])
rotate([0,45,0])
cube(2*[BrakeRad,2*BrakeRad,BrakeRad],center=true);
}
translate([0,Magnet.y/2 - Holder.y - Protrusion/2,Magnet.z/2 + Plate + Protrusion/2])
cube(Magnet + [0,Protrusion,Protrusion],center=true);
}
}
// Shift stud cap
// With passage for harness cable
CapBlock = [18,18,16.5];
module ShiftCap() {
Rounding = 3.5;
CapM = 3.0;
StudBase = [12.5,12.5,4.5];
Stud = [5.0,9.3,15.5];
difference() {
hull() {
translate([0,0,CapBlock.z - 0.5])
PolyCyl(Washer5[OD],0.5,12);
for (i=[-1,1], j=[-1,1])
translate([i*(CapBlock.x/2 - Rounding),j*(CapBlock.y/2 - Rounding),0])
sphere(r=Rounding,$fn=12);
translate([-CapBlock.x/2,-Harness[ID]/2 - StudBase.y/2,StudBase.z/2])
rotate([0,90,0])
cylinder(d=Harness[ID] + 2*WallThick,h=CapBlock.x,$fn=12);
}
translate([0,0,-(FrameTube.z/2 - CapM)])
Frame();
PolyCyl(Screw5[ID],2*CapBlock.z,6);
PolyCyl(Stud[OD],Stud[LENGTH],12);
translate([0,0,StudBase.z/2])
cube(StudBase,center=true);
translate([0,-StudBase.y/2,StudBase.z/2])
cube(StudBase + [0,-StudBase.y/2,0],center=true);
translate([-CapBlock.x,-Harness[ID]/2 - StudBase.y/2,StudBase.z/2])
rotate([0,90,0])
cylinder(d=1.5*Harness[ID],h=2*CapBlock.x,$fn=12);
}
}
// Head tube clip for harness cable joint
module HeadClip() {
CableOD = Harness[OD];
difference() {
linear_extrude(height=HeadTube[LENGTH],convexity=10)
difference() {
hull() {
circle(d=HeadTube[ID] + 2*WallThick,$fn=FrameSides);
translate([0,-(HeadTube[ID] + CableOD)/2])
rotate(180/(FrameSides/2))
circle(d=CableOD + 2*WallThick,$fn=FrameSides/2);
}
circle(d=HeadTube[ID] + HoleWindage,$fn=FrameSides);
translate([0,-(HeadTube[ID] + CableOD)/2])
rotate(180/(FrameSides/2))
circle(d=CableOD + HoleWindage,$fn=FrameSides/2);
translate([0,-HeadTube[ID]/2])
square(0.75*CableOD,center=true);
translate([0,HeadTube[ID]])
square(2*HeadTube[ID],center=true);
}
translate([0,-(HeadTube[ID]/2 + CableOD + WallThick - CableTie.z/2),HeadTube[LENGTH]/2])
cube([HeadTube[ID],CableTie.z,CableTie.y],center=true);
for (i=[-1,1])
translate([i*(HeadTube[ID]/2 + WallThick - CableTie.z/2),0,HeadTube[LENGTH]/2])
cube([CableTie.z,HeadTube[ID],CableTie.y],center=true);
}
}
// Programming cable case
ProgCavity = [60.0,18.0,7.0];
ProgBlock = [70.0,24.0,13.0];
ProgCableOD = 4.0;
module ProgrammerCase() {
difference() {
hull() {
for (i=[-1,1], j=[-1,1])
translate([i*(ProgBlock.x/2 - CornerRadius),j*i*(ProgBlock.y/2 - CornerRadius),-ProgBlock.z/2])
cylinder(r=CornerRadius,h=ProgBlock.z,$fn=12);
}
translate([-ProgBlock.x,0,0])
rotate([0,90,0])
PolyCyl(ProgCableOD,3*ProgBlock.x,6);
cube(ProgCavity,center=true);
translate([0,0,ProgBlock.z/2 + ProgCavity.z/2 - EmbossDepth])
cube(ProgCavity,center=true);
translate([0,0,-(ProgBlock.z/2 + ProgCavity.z/2 - EmbossDepth)])
cube(ProgCavity,center=true);
}
translate([0,4,ProgBlock.z/2 - EmbossDepth])
linear_extrude(height=EmbossDepth)
text(text="Bafang BBS02",
size=5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
translate([0,-4,ProgBlock.z/2 - EmbossDepth])
linear_extrude(height=EmbossDepth)
text(text="Programmer",
size=5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
translate([0,4,-ProgBlock.z/2])
linear_extrude(height=EmbossDepth)
mirror([1,0])
text(text="Ed Nisley",
size=5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
translate([0,-4,-ProgBlock.z/2])
linear_extrude(height=EmbossDepth)
mirror([1,0])
text(text="softsolder.com",
size=5,spacing=1.00,font="Bitstream Vera Sans:style=Bold",
halign="center",valign="center");
}
// Half case sections for printing
module HalfCase(Section = "Upper") {
intersection() {
translate([0,0,ProgBlock.z/4])
cube([2*ProgBlock.x,2*ProgBlock.y,ProgBlock.z/2],center=true);
if (Section == "Upper")
ProgrammerCase();
else
translate([0,0,ProgBlock.z/2])
ProgrammerCase();
}
}
//----------
// Build them
if (Layout == "Frame")
Frame();
if (Layout == "DispMount")
DispMount();
if (Layout == "BrakeMagnet")
BrakeMagnet();
if (Layout == "ShiftCap")
ShiftCap();
if (Layout == "HeadClip")
HeadClip();
if (Layout == "BuildClip")
rotate([-90,0,0])
HeadClip();
if (Layout == "BuildShiftCap")
translate([0,0,CapBlock.z])
rotate([180,0,0])
ShiftCap();
if (Layout == "Case")
ProgrammerCase();
if (Layout == "NutMold")
NutMold();
if (Layout == "Upper" || Layout == "Lower")
HalfClamp(Station,Layout);
if (Layout == "Block") {
ClampBlock(Station);
if (false)
color("Red", 0.3)
Frame();
}
if (Layout == "AllBlocks") {
gap = 3*Block.x;
for (i=[0:4])
translate([i*gap - 2*gap,0,0])
Clamp(i);
if (true)
color("Red", 0.3)
Frame();
}
if (Layout == "BuildBlock") {
gap = 5.0;
translate([gap,0,Block.x/2])
rotate([0,90,0])
HalfClamp(Station,"Upper");
translate([-gap - Block.z/2,0,Block.x/2])
rotate([0,90,0])
HalfClamp(Station,"Lower");
}
view raw Terry - Bafang conversion.scad hosted with ❤ by GitHub
Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Terry Head Tube Clip

The Bafang BBS02 runs a fat “harness cable” from the motor to the four handlebar components (two brake sensors, throttle, and display), with a lump covering the junction where the four smaller cables emerge. Securing the lump to the head tube seemed like a good way to keep the motion in the (presumably) more flexible smaller cables:

Terry Bafang - headset cable clip - front
Terry Bafang – headset cable clip – front

From the rear:

Terry Bafang - headset cable clip - rear
Terry Bafang – headset cable clip – rear

I later bound the four connectors into a cluster using cable ties to further reduce the clutter and keep them from tapping the top tube.

The clip captures the cable tie in those indents:

Terry - Bafang head tube clip - solid model
Terry – Bafang head tube clip – solid model

The overhangs require easy cleanup with a square file to get rid of a few droopy threads. Avoid the temptation to print it standing up as an arch, because you want the perimeter threads to go around the whole thing, not across the thinnest sections. Trust me on this.

The OpenSCAD source code:

module HeadClip() {

CableOD = Harness[OD];

    difference() {
        linear_extrude(height=HeadTube[LENGTH],convexity=10)
            difference() {
                hull() {
                    circle(d=HeadTube[ID] + 2*WallThick,$fn=FrameSides);
                    translate([0,-(HeadTube[ID] + CableOD)/2])
                        rotate(180/(FrameSides/2))
                            circle(d=CableOD + 2*WallThick,$fn=FrameSides/2);
                }
                circle(d=HeadTube[ID] + HoleWindage,$fn=FrameSides);
                translate([0,-(HeadTube[ID] + CableOD)/2])
                    rotate(180/(FrameSides/2))
                        circle(d=CableOD + HoleWindage,$fn=FrameSides/2);
                translate([0,-HeadTube[ID]/2])
                    square(0.75*CableOD,center=true);
                translate([0,HeadTube[ID]])
                    square(2*HeadTube[ID],center=true);
            }
        translate([0,-(HeadTube[ID]/2 + CableOD + WallThick - CableTie.z/2),HeadTube[LENGTH]/2])
            cube([HeadTube[ID],CableTie.z,CableTie.y],center=true);

       for (i=[-1,1])
            translate([i*(HeadTube[ID]/2 + WallThick - CableTie.z/2),0,HeadTube[LENGTH]/2])
                cube([CableTie.z,HeadTube[ID],CableTie.y],center=true);
    }
}

I briefly thought of holding two pieces together around the head tube with M3 screws, but came to my senses: a cable tie is exactly what you want when holding a cable in place. Right?

Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Terry Cable Stop Cap

The Terry Symmetry had shift cables running along the down tube, with cable housing stop bushings at the top:

Terry Bafang - OEM shift stop
Terry Bafang – OEM shift stop

Without the front derailleur and with the wiring harness cable on the left side, a tidy cap seemed in order:

Terry Bafang - shift stop cap
Terry Bafang – shift stop cap

The oversize passage give the cable a little flex room, although that’s probably unnecessary. I reused the original M5 screw, with a washer to spread the load.

The solid model is basically a hull around some cylinders:

Terry - Bafang shift cap - solid model
Terry – Bafang shift cap – solid model

The interior matches the stud brazed onto the downtube:

Terry - Bafang shift cap - interior - solid model
Terry – Bafang shift cap – interior – solid model

The only practical way to build the thing required a brim stabilizing it on the platform:

Terry - Bafang shift cap - slice preview
Terry – Bafang shift cap – slice preview

My usual 0.25 mm layers came out a bit crude on the vast overhang, but 0.15 mm layers worked fine.

The OpenSCAD source code snippet:

CapBlock = [18,18,16.5];

module ShiftCap() {

Rounding = 3.5;
CapM = 3.0;
StudBase = [12.5,12.5,4.5];
Stud = [5.0,9.3,15.5];

    difference() {
        hull() {
            translate([0,0,CapBlock.z - 0.5])
                PolyCyl(Washer5[OD],0.5,12);
            for (i=[-1,1], j=[-1,1])
                translate([i*(CapBlock.x/2 - Rounding),j*(CapBlock.y/2 - Rounding),0])
                    sphere(r=Rounding,$fn=12);
            translate([-CapBlock.x/2,-Harness[ID]/2 - StudBase.y/2,StudBase.z/2])
                rotate([0,90,0])
                    cylinder(d=Harness[ID] + 2*WallThick,h=CapBlock.x,$fn=12);
        }

        translate([0,0,-(FrameTube.z/2 - CapM)])
            Frame();

        PolyCyl(Screw5[ID],2*CapBlock.z,6);

        PolyCyl(Stud[OD],Stud[LENGTH],12);

        translate([0,0,StudBase.z/2])
            cube(StudBase,center=true);

        translate([0,-StudBase.y/2,StudBase.z/2])
            cube(StudBase + [0,-StudBase.y/2,0],center=true);

       translate([-CapBlock.x,-Harness[ID]/2 - StudBase.y/2,StudBase.z/2])
            rotate([0,90,0])
                cylinder(d=1.5*Harness[ID],h=2*CapBlock.x,$fn=12);

    }
}

Of course, I needed three tries to get the correct dimensions, but that’s what rapid prototyping is all about.

Machine Shop, Recumbent Bicycling, Software

Bafang BBS02: Terry Brake Sensor

The old-school “aero” brake levers on Gee’s Terry Symmetry bike have rubberoid cushion covers, so I slid the Bafang brake sensors inside:

Terry Bafang brake sensor - front
Terry Bafang brake sensor – front

They make the grips somewhat wider, but I can’t figure out a less destructive way of installing the things.

I glued the magnet inside a holder contoured to fit the space available:

Terry - Bafang brake sensor - solid model
Terry – Bafang brake sensor – solid model

Knocking the corners off makes it much more finger-friendly.

It’s unobtrusive with the handle released:

Terry Bafang brake sensor - released
Terry Bafang brake sensor – released

When you squeeze the lever, your fingers are nowhere near the magnet:

Terry Bafang brake sensor - pulled
Terry Bafang brake sensor – pulled

The lower edge actually slides along the brake lever housing without touching, but it’s a near thing.

Those are the same magnets I used for the Bafang brake sensors on Mary’s Tour Easy, once again aligned to aim the strongest volume of the magnetic field toward the sensor. The brake sensors activate just before the pads touch the rims and release with the magnets a few millimeters away from the sensors.

A complete coat of JB Plastic Bonder urethane adhesive covers each magnet to both isolate it from the weather and conceal the fact that they’re recycled from a power toothbrush.

Now that I know they work in this position, I must ease adhesive underneath the sensors so they don’t move around under normal hand pressure.

The OpenSCAD source code snippet:

module BrakeMagnet() {

    Magnet = [10.5,3.0,5.5];
    Plate = 2*ThreadThick;
    BrakeRad = 10.0;            // brake handle curve Radius
    Holder = [2*BrakeRad,7.0,Magnet.z + Plate];


    difference() {
        intersection() {
            translate([0,-BrakeRad,0])
                rotate(180/24)
                    cylinder(r=BrakeRad,h=Holder.z,$fn=24);
            translate([0,BrakeRad - Holder.y,Holder.z/2])
                cube([2*BrakeRad,2*BrakeRad,Holder.z],center=true);
            translate([0,0,-2*BrakeRad/sqrt(2) + Holder.z - 3.0 + BrakeRad])
                rotate([0,45,0])
                    cube(2*[BrakeRad,2*BrakeRad,BrakeRad],center=true);
        }
        translate([0,Magnet.y/2 - Holder.y - Protrusion/2,Magnet.z/2 + Plate + Protrusion/2])
            cube(Magnet + [0,Protrusion,Protrusion],center=true);
    }

}