Posts Tagged Improvements
HON Lateral File Cabinet Shelf Bumper Replacement
Posted by Ed in Home Ec, Machine Shop, Photography & Images on 2020-02-26
Somewhat to our surprise, our “new” HON Lateral File Cabinets include a pop-out shelf:
The trick: push the bar inward against fairly stiff spring pressure, release it suddenly, watch it pop out maybe half an inch, get some fingers under the front edge, then pull it outward:
Obviously, opening the drawer above the shelf will sweep whatever you put there onto the floor and opening the drawer below seems futile. I suppose it produced a bullet item on the features list.
Note that the topmost “drawer” is also called a “shelf”, because the front cover slides up-and-inward to reveal the contents. Should you stand eight feet tall, you might be able to look down on that shelf, but we mere mortals barely see its contents at eye level.
Dismantling the cabinets preparatory to deep cleaning revealed a pair of rubber bumpers along the rear edge of the shelf:
The slightly angled front side of the bumper (on the right) collides with a crossbar below the drawer just above it, preventing you from pulling the shelf entirely out of the cabinet.
Remove the bumper by pressing down and rearward (to the left), shoving the protruding lip into the slot with a thumb / screwdriver, then pull it upward through the slot:
The second cabinet had only one bumper, so I traced it twice onto a rubber sheet half as thick as the OEM bumper, bandsawed the shapes, and introduced them to Mr Belt Sander for cleanup:
Jammed side-by-side into the slot, they’ll serve the purpose:
As with the replacement foot on the first cabinet, they’re not the prettiest things you’ve ever seen, but Mary doesn’t expect to use the shelf and they’ll never actually bump into anything.
Even the Pixel phone’s HDR image processing has trouble dealing with dark gray objects on a black background in dim light …
Refrigerator Coil Wand Adapter Rebuild
Posted by Ed in Home Ec, Machine Shop on 2020-02-25
After five years, the adapter between the Kenmore Progressive vacuum cleaner and the long wand required to reach inside the refrigerator evaporator coils broke at the latch opening:
A quick fix let me continue the mission:
A better fix required a few minutes of OpenSCAD tweakage and a few hours of hands-off build time:
The fitting ID is now 2 mm smaller, the 3D honeycomb infill is 25%, and (contrary to the picture) it now has 4 perimeter threads. It’s a two-line change from the last time:
OEMTube = [35.0 - 2.0,35.0,41.7,40.5,30.0]; // main fitting tube
… then, inside MaleFitting() …
cylinder(d1=OEMTube[ID2],d2=OEMTube[ID1],h=2*OEMTube[LENGTH] + 2*Protrusion);Those will propagate to anything I build from now on, although this is the first latch fracture.
Gotta love it when 3D printing lives up to the hype!
The Return of High-Reliability / High-Availability Trash Cans
Five years ago, robotic trash cans were a thing on Vassar’s campus, including this duo in front of Vassar’s library:
I infer the robotics did not work out as anticipated.
Bird Box Entrance Reducers: Round 2
Posted by Ed in Home Ec, Machine Shop on 2020-02-19
One of the bird box entrance reducers I installed nigh onto a decade ago is still on duty, although downy woodpeckers definitely want a larger hole:
Another reducer had gone missing over the years, so I made one from a length of PVC pipe:
It started as 1-½ PVC pipe, 1-⅞ inch actual OD and should fit into a 1-½ hole, so I measured 1.5 × 3.15 around the circumference, bandsawed out the excess, draped it over a 1-½ Forstner bit, toasted it with a heat gun, and squashed it so it’s just a little bit bigger than the (enlarged!) hole in the box.
Now the entrance is 1-¼ (-ish), just like it should be:
The bird box in the front yard has been attracting starlings, in addition to serving as a hawk perch:
The oblong hole required advanced manufacturing techniques:
The front face should be too slick for larger birds and the little ones will zip right into the hole:
The two starlings who’d been evaluating the box seem to have moved on; we doubt they’re now homeless.
The OpenSCAD source code as a GitHub Gist:
Kensington Expert Mouse Scroll Ring Fix
Posted by Ed in Electronics Workbench, PC Tweakage on 2020-02-17
Apparently the newest Kensington Expert “Mouse” trackballs have a hack re-orienting the scroll ring quadrature detector. The picture from my original writeup shows the previous situation:
The quadrature detector, the black block on the left, is oriented with its lens (and, thus, the actual detectors) pointed away from the IR emitter. I thought it might be an assembly screwup, but it’s actually worse: the PCB layout is wrong.
A note from Tristan in NZ explains the situation:
So I have a later model than yours. It has a 2nd PCB chunk between where the legs normally would be. Just a floating piece with two holes for the legs, holding the legs from the board […] to the main board.It is also pointing the correct way (with the lens towards the three leg emitter).
The new quad detector has only three pins and no convex lens, but the active area now faces the emitter across the gap.
Because the interposer PCB occupies the space previously devoted to the emitter & detector leads, Kensington apparently soldered the new parts directly to the top surface without any clearance:
It’s like they failed to put through-vias to the rear or didn’t route them to the bottom another way, hence the solder is under the component
Tristan managed to wreck the detector while attempting to re-solder the intermittent joints, a situation I’m painfully familiar with. He replaced it with a quad detector harvested from a mid-90s optical mouse and it’s back in operation.
So I think the correct “fix” for the old-style PCBs (without the new interposer) is to unsolder the detector, rotate it so the lens faces the emitter, then somehow rewire the pins to the original pads. This won’t be easy and definitely won’t be pretty, but as long as it’s pointed in the right general direction it should work:
mine works off axis quite a bit
Should either of my Expert Mouse trackballs fail, now I know what to do
Many thanks to Tristan for reporting his findings!
Video-rated MicroSD Card Status Report
Posted by Ed in Electronics Workbench, Photography & Images, Recumbent Bicycling, Science on 2020-02-05
Having just returned from the fourth ride of the season, it’s worthwhile to note how the MicroSD cards in the cameras are doing.
The Sony HDR-AS30V helmet camera has been running a 64 GB Sandisk high-endurance video-rated card since late August 2017:
In those 29 calendar months (maybe 20 riding months) I’ve ridden 4500-ish miles at perhaps 12 mph, so call it 375 hr = 22.5 k min. The camera fills a 4 GB file every 22.75 min, so it’s recorded 1000 files = 4 TB, which is 62× its capacity. This is better than the defunct Sandisk Extreme Pro card (3 TB & 50×) and much much better than the Sony cards (1 TB & 15×), although I have caught the camera in RCVR mode maybe twice, which means the card or camera occasionally coughs and reformats itself.
The Cycliq Fly6 rear camera uses a Sandisk 32 GB card that’s been running flawlessly since late 2017:
The new 16850 lithium cell continues to work fine, too.
The SJCam M20 rear camera also uses a Sandisk 32 GB high-endurance card and has worked fine since early 2018. An external battery eliminated all the hassle of its feeble internal batteries, although the one that’s been in there has faded to the point of just barely keeping the clock ticking over during winter weeks without rides:
All in all, paying the premium for video-rated MicroSD cards has been worthwhile!
Homage Tek CC: Subscripts & Superscripts
Posted by Ed in Electronics Workbench, Software on 2020-02-04
The GCMC typeset() function converts UTF-8 text into a vector list, with Hershey vector fonts sufficing for most CNC projects. The fonts date back to the late 1960s and lack niceties such as superscripts, so the Homage Tektronix Circuit Computer scale legends have a simpler powers-of-ten notation:
Techies understand upward-pointing carets, but … ick.
After thinking it over, poking around in the GCMC source code, and sketching alternatives, I ruled out:
- Adding superscript glyphs to the font tables
- Writing a text parser with various formatting commands
- Doing anything smart
Because I don’t need very many superscripts, a trivial approach seemed feasible. Start by defining the size & position of the superscript characters:
SuperScale = 0.75; // superscript text size ratio
SuperOffset = [0mm,0.75 * LegendTextSize.y]; // ... baseline offsetHalf-size characters came out barely readable with 0.5 mm Pilot pens:
They’re legible and might be OK with a diamond drag point.
They work better at 3/4 scale:
Because superscripts only occur at the end of the scale legends, a truly nasty hack suffices:
function ArcLegendSuper(Text,Super,Radius,Angle,Orient) {
local tp = scale(typeset(Text,TextFont),LegendTextSize);
tp += scale(typeset(Super,TextFont),LegendTextSize * SuperScale) + SuperOffset + [tp[-1].x,0mm];
local tpa = ArcText(tp,[0mm,0mm],Radius,Angle,TEXT_CENTERED,Orient);
feedrate(TextSpeed);
engrave(tpa,TravelZ,EngraveZ);
}The SuperScale constant shrinks the superscript vectorlist, SuperOffset shifts it upward, and adding [tp[-1].x,0mm] glues it to the end of the normal-size vectorlist.
Yup, that nasty.
Creating the legends goes about like you’d expect:
ArcLegendSuper("pF - picofarad x10","-12",r,a,INWARD);Presenting “numeric” superscripts as text keeps the option open for putting non-numeric stuff up there, which seemed easier than guaranteeing YAGNI.
A similar hack works for subscripts:
With even more brutal code:
Sub_C = scale(typeset("C",TextFont),LegendTextSize * SubScale) + SubOffset;
<<< snippage >>>
tp = scale(typeset("←----- τ",TextFont),LegendTextSize);
tp += Sub_C + [tp[-1].x,0mm];
tp += scale(typeset(" Scale -----→",TextFont),LegendTextSize) + [tp[-1].x,0mm];The hackage satisfied the Pareto Principle, so I’ll declare victory and move on.
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