Next is the breakdown of the trucks.
The trucks are snapped into the frame. Once the truck wires are unsoldered from the circuit board and the board is removed the trucks can simply be pulled out from the bottom of the frame. Some gentle rocking while pulling it out will aid in removal. This particular truck was not properly installed at the factory. The arrow shows where the wire, instead of going straight up was bent into a U-shape over the truck's frame. When the truck was installed in the frame the wire ended up pinched between the truck's frame and bottom of the loco's frame. This restricted its rocking motion and could have caused problems when the loco was running over rough track or starting up or down an incline.
Removing the sideframes/gear-cover exposes the gears in the truck. All metal axles are fixed in the frame (they do not rotate) and the gears are free to rotate and slide sideways. It looks like there was some problem with the large thin center idler gear sliding too far on the axle, so there is a piece of what looks like black heat-shrink plastic tubing installed on the axle. But that tubing is rather very short.
Side of the truck's frame showing the electric pickup wipers and the axle ends. What seems unusual is that there are 3 different diameters of axles used in this truck. The worm-wheel/compound gear uses a 0.8mm axle, the idler gears use 1mm axles and the wheelsets have 1.5mm axles. I'm puzzled as to the reason why the worm-wheel/compound gear needs a 0.8mm axle instead of the 1mm ones used with the other gears.
The wheelsets use 1.5mm axle and one wheel is insulated using a plastic insert as shown in this photo. The wheel's face profile is not realistic, but not strange looking like some other manufacturers use. This is not a problem since the wheel face is mostly hidden by the truck's sideframes. The wheel diameter is 0.249" (40") and it has a 0.020" flange.
The left wheel is the one which has a traction tire (but it is shown removed). This model has 2 traction tires - one per truck. In this photo, the traction tire would be on the left wheel, but I removed it for the photos. Thus, there is a shallow groove (for the traction tire) visble in the tread of the left wheel.
When I first noticed that Arnold used wheelsets with plastic gears pressed onto metal axles, I was a bit concerned. I have seen several locomotives using this type of design, where the the plastic gear splits after a couple of years due to excessive stress from the axle. But upon further examination I felt confident that the gear on this locomotive will not be prone to splitting. Instead of making the hole in the gear undersized, and depending on that tight fit to lock the gear onto the axle, Arnold uses linear knurling of the axle to positively lock the gear in place. The gear can be fairly easily slid along the axle, off the knurled area, which means that there isn't much stress generated in the gear's center. Also noteworthy is the groove on the axle end which holds the insulated wheel. That groove positively locks the plastic bushing in the wheel's center, preventing it from getting out of gauge.
As it is quite common in N scale model locomotives the wheel gauge is tight, as shown here placed against the NMRA gauge. All the wheelsets on both of my models were tight in gauge.
They ran ok on Peco and on standard Atlas code 80 track, but they would not run over Atlas code 55 turnouts. They would derail at the frog. I contacted Hornby/Arnold about this, and I was told that the tight-gauge I've observed on my models was not a widespread problem.Due to the wheelset's construction it will be somewhat difficult to re-gauge the wheels. In order to do that properly (keeping the gear in its proper location on the axle) both wheels would have to be pushed outward on the axle. The insulated wheel might not be too difficult to move but the one directly press-fit on the axle will most likely be tough to move.
I used a Mascot brand gear puller to get the wheels properly gauged. I moved both wheels out to keep the gear in proper alignment with the other gears.
Here are all the gear components of the trucks (degreased and ready for reassembly).
The gears reinstalled in the truck frame. Visible is the longer piece of black tubing
I installed on the center idler axle.
Components of the universal joint and the worm. The worm shaft is a bit unusual. It has a 1.5mm diameter where the bearings are but then it steps down to 1mm to accept the universal coupling. I don't understand why Arnold didn't just make the entire shaft 1mm in diameter. Smaller shaft creates less friction in the bearings and there would be fewer machining steps involved. Maybe the model's manufacturer already had either the bearings or the worms readily available with 1.5mm bore and only had universal couplings with 1mm bores?
The bearings are made of brass. It might be sintered brass but I'm not sure - it looks like solid brass to me. There are also clear plastic trust washers on both sides of the worm, and there isn't much forward/backward play when the bearings are installed in the loco's frame. The plastic universals look similar to the ones I've seen used in brass models.
Next 3 photos show the assembled worm, bearings, universal coupling and the motor's flywheel (I use that term loosely).
The motor end of the universal coupling fits in the flywheel and the motor shaft fits loosely in the bore in the coupling, It is a somewhat floppy connection.
Here is the worm and universal coupling installed in the loco's frame and coupled to the motor. This is a single-start worm.
The final gear ratio of this model is 35:1. That is quite good for a switcher with a high-revving coreless motor. The model should be capable of reliable slow speeds and it should have plenty of low-end pulling power.
UPDATE: I ran this model on layout using Peco track. It is well-built layout with excellent track work. As expected, this model has an excellent slow speed performance and the top speed is much lower than average diesel locos. It can really crawl! I'm sure this is due to well chosen gear ratio.
But the electric pickup is spotty (even on straight freshly cleaned track with freshly cleaned wheels). The same track where another loco has no problems picking up electricity. The spotty pickup is most apparent when the loco is running at a crawl. The problem might be the blackening layer on the wheels and I'm sure the 2 traction tires aren't helping either. Maybe things will improve once the blackening wears off the treads. Also, once spare parts are available I'll get rid of the traction tires.
The walkways have a "tread pattern" molded on them. But it is not quite like the real thing, and way out of scale. It looks like rows of rivets.
The tread pattern on walkways of N scale models is one of the things modelers disagree about. To me a truly-scaled tread pattern in N scale model would be so fine and shallow that it would probably disappear under a coat of the not-to-scale-thickness paint we use on our models. The oversize tread patterns which manufacturers use to me all look out-of-scale and unrealistic. But many models want that oversize tread pattern and complain of the model's walkways are smooth. As far as this model goes, I don't have any prototype photos to check whether what Arnold uses is a real tread pattern for this loco, but I doubt it was just a bunch of rivet-like bumps. So to me this in not good feature on this model.
I was also asked how the shell was put together. The next 2 photos show the inside of the shell.
The walkway is separate and it is not glued on. The hood and cab are also separate pieces which snap together but the snaps on the sides of the hood have some solvent glue flowed into them. However I think that they can still be separated without any damage. The handrails are super-glued to the shell. The windows are also glued in from the inside - those might be a bit tougher to remove. The stack, bell and headlights are also glued in.
When reassembling the model I recommend tucking the truck pickup wires into the worm opening as shown in this photo. That will provide some extra wire length when the truck swings and possibly extra length of wire if it gets damaged during soldering.
Here is the loco chassis and circuit board reassembled with all the wires trimmed and soldered to the board. It now looks much neater than the original assembly. I also lightly oiled all the shafts and applied a small amount of Teflon grease to all the gears. A hint for resoldering the wires: The original lead-free solder used in this model has a fairly high melting point (which if the soldering is not done fast enough can easily melt the delicate insulation on the wires). I had to crank my soldering iron's temperature up to around 750 degrees F to melt that solder. After unsoldering the wires I used solder wick and some paste rosin flux to remove all of the lead-free solder from the solder pads for the wires. When reattaching the wires I first trimmed the wires and tinned them using standard 60/40 electronic solder which has a lower melting temperature (I select 650 degrees F on my iron). Then I solder those wires back, again using the 60/40 solder. The lower soldering temperature is less damaging to the wire insulation.
The couplers used in this model are a bit unusual. These couplers were initially used in the Arnold's initial U.S. prototype model: the U25C. But I don't own that model so I never had a chance to examine these couplers up close until now.
The coupler follows the typical split-shank design utilized in many MT (Micro-Trains) N scale couplers. But the coupler head itself is quite a bit smaller than that of the the MT coupler. Here is the Arnold coupler on the left, with N scale Micro-Trains coupler on the right. Appearance-wise the Arnold coupler's shape and size is closer to the prototype knuckle coupler. But the overall molding quality is not quite up to MT standard. The surface of the Arnold's parts is rougher, the mold draft angles seem to be a bit larger, and there is some flash on the parts (a piece of flash is visible in the photo above). Also, the metal uncoupling pin is round in cross section so it can easily rotate out of proper alignment. MT uncoupling pins have flattened shape so they cannot rotate out of alignment.
There also seems to be a bit of a compatibility problem between the Arnold and MT couplers as shown in the above photo. I'm surprised that this was not mentioned when the U25C (which was the 1st model to use this coupler) was introduced. While I have not yet tested this model on a layout, I clearly see this problem on a piece of test track on my work bench. As the above photo shows the opening inside of the Arnold coupler knuckle is too shallow. The MT coupler hits the back of the opening and the knuckles do not clear each other to couple properly. If some force is applied to shove them together (or if one of the couplers is swung slightly to the side then they will couple. But a gentle-coupling doesn't seem possible. I guess I will have to test this loco on a layout to see how well it will couple to other brand knuckle couplers. This problem might also be fixable with some small trimming of the Arnold coupler. I will revisit this coupler in more details in the future. It is a good looking coupler - too bad that it doesn't seem to work very well. I think that the opening behind the knuckle probably only needs to be about 0.005" deeper for it to work more reliably with MT couplers.
UPDATE: I tested the loco on a layout and it was not easily coupling to MT coupler-equipped cars. I The couplers had to be slammed together hard to get the couplers to coupler. But the Arnold couplers easily coupled to Accumate couplers. Those were the only 2 kinds I had handy to try.
Overall, I'm quite happy with the model's appearance and performance. Thanks to its gearing ratio of 35:1, and a coreless motor with good torque, this model has excellent slow-speed performance and realistic top speed. It was able to pull 30 40' Micro-Trains boxcars on a flat and tangent track, but that number will go down as the train travels through curves or up an incline. Small switching locomotives don't normally pull 30 cars in any case. But the jury is still out on the longevity of those low-end coreless motors, since they do not have replaceable brushes. Hopefully replacement motors will be available from Arnold for years to come. While this model is not 100% perfect, Arnold has a winner on their hands.
On the other hand, I'm a bit put off by the price when comparing this model to much better-made models from Kato. Just like Victor Miranda says, I think that for what I get here for the price, the model is overpriced. However, it is the only game in town...
EDIT: Photobucket disaster - moved all the photos to local gallery.
