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Wednesday, 23 March 2016

B25: Refitting the head and barrel. Oil filter swap and sump



Having restored all the threads on these studs 26 tpi BSF and BSC on the 1/4 inch and 26, 22 tpi on the 5/16 I fitted all studs back into the head. I have decided to use the second head as this one hasn't been skimmed at all and so has more life ahead of it.

Steel studs going into ally should (I believe)  always be lubricated- either with oil, or in this case Loctite threadseal 2701. I applied this to all threads and then screwed the BSF threaded ends into the head. I used the stud remover to tighten all to firm hand tightness, they will grip through the upward tug of the nuts when these are tightened rather than the twist of the steel stud in the head and so studs don't need a lot of torque into the head itself.

I found that I was lacking one of the longest 1/4 inch studs and made a spare one using 1/4 inch stainless steel rod.- Note from experience - don't try threading stainless unless you have HSS taps/dies! I simply blunted the carbon steel cheapo versions that I had and needed to order  the real-deal kit.

Head steady in place- two washers underneath each side to act as spacers
I ended up making three new studs but the rocker box went on fine after that, tightening small nuts to 7 and larger ones to 10 ftlb respectively. I had been concerned about the state of the cylinder base gasket and was also worried that taking the head off might have disturbed it anyway so I decided to renew it as well.


The barrel pulled off easily, here using wood strips to stop the piston flapping about and getting damaged.
Bottom of barrel- signs of base gasket having leaked- I recall it was a bit oily about here so definitely a good idea to pull the barrel. Bore looks good- some original honing visible and no sign of a ridge at the top.
Bottom of barrel cleaned...

... and the top

Barrel cleaned up nicely with brass wire brush on the Dremmel, careful to get the burnt on carbon off the top cylinder spigot and around the liner base


Given the evidence of leakage I decided to take a leaf out of the Lotus book and use a gasket sealant - in this case Wellseal. Lotus use this on all gaskets and I think its a good idea here. If its good enough for Mr Chapman its got to be way good enough for the likes of me! Paint it on to the barrel and then apply the gasket


Gasket bedded into Wellseal



Then paint the other side of the gasket...


... and check that the oil holes are not obstructed.

It was at this point that the best laid plans etc etc -anyway they came unstuck: In order to install the barrel I needed to compress the rings. If you are gifted with a rock hard grip and insensitive calloused fingertips you can probably do this by hand- I wanted to use a ring compressor. I have the Laser 5066 Universal motorcycle piston ring compressor kit which should cover this piston size... and it does... but unfortunately the position of the studs means that the clamp cant be fitted!!! Much swearing and aborted attempts later (all the while with my Wellseal going off) there was no alternative but to remove the front stud to gain access and refit it later.
Front stud removed

 The ring compressor then fitted a treat BUT... the stud is wider at its base than than at the top and cannot be inserted downwards through the barrel so fit the compressor and insert the stud as you lower the barrel down...
Compressor in place- just need to...

 Feed the stud in (coarse thread down) from the bottom of the barrel and slip it into alignment with the hole in the crankcase before...
 Lowering the barrel- with the compressor in place its now a doddle
 Remove compressor, lower fully and lastly tighten the stud back down into the crankcase (oiled thread)
Push rods on tappets and angle for their respective rockers.
 Fit push rods into the tappets - intake is at the front- don't mix them up. Apparently the exhaust should have a red top- mine was marked but poorly. Fit a new head gasket - I think these can be reused- there seem to be a lot of used ones on Ebay anyway, but I think they would need annealing. I just bought a new engine set so I would have everything I might need.
 Lower on the head- you need to fit this at first positioned on top of the push rods but facing out to the left of the bike. Then you can swivel it back around the push rods and line it up on the studs. Note new head gasket in place.
 Check the rockers engage on the pushrods as the head comes down- here the inlet...

...and here the exhaust. You will need some form of hook tool to position the push rods as the head comes down, I used a pipe cleaner. This job would be easier with three hands and slender fingers but it can be done. You can get some movement on the rockers by depressing them with a finger through the rocker cap and then lowering them back onto the top of the push rods before the head is fully down- might be best to make a wooden spacer about 1-2 cms thick to support the head while the rockers and push rods are in this "sweet zone" where there is just sufficient vertical room to lift the rockers enough to let you move the push rods underneath, but tight enough that lowering the rocker then engages the rod top and holds it in place while you do the other, and of course lastly remove the spacer and lower the head.

BUT- all this fiddling about can cause the base of the push rods to jump out of the tappet/cam follower at the bottom- and as this is now invisible the only way to check is to fit the head loosely hand tight is good enough  (don't need to torque down) and rotate the motor to check both valves operate and in the expected sequence. On my first attempt I had somehow dislodged the inlet so it is worth checking.



Finally torque down the head- as I suspected during dis-assembly, it is impossible to torque the two 5/15 nuts on the studs recessed below the rocker box... even with a crowfoot spanner. I torqued down what I could and just made sure these seemed to be "as tight"



You can make a compound torque wrench like this using a socket adapter to attach a combination spanner to the torque wrench and the C end to slip onto the nut- no good for tightening really but just to check final torque. I still think this idea has a lot going for it but as the torque is now measured some 15 cm from the actual nut head I suspect the reading I'm looking for would differ- the maths of this defeated me so I just went for "tight".
Before I could finish the bike, I needed to sort out the leaking tank. This has a filter socket combined with a banjo union at its base. The banjo is sealed by two washers - I had expected copper but they are specified as "fibre" in the parts list (The Starfire shown)
Banjo washers are shown with different numbers but they have the identical BSA part number so in fact are the same.
 The washers should be the same, but in my case there were two different washers fitted of different thicknesses.
Note different washers and hole in filter gauze
 There is also a hole in the filter at the base- this would let any crud straight through so the filter will need changing. It is possible just to get the gauze filter (RGM Norton have one that should fit) but this is about half the cost of a new unit and still needs soldering on in a neat and tight fashion- it seems easier just to replace the lot.
Thread in base of oil tank

...and here is the rub! The filter unit can only screw into the base of the tank so far- eventually it screws up hard against the end of the threads. At this point the banjo section is left protruding but the washers have to seal tight before you run out of thread- and in my case they hadn't. What this means is that the thickness of the washers is critical- anything too thin will never be able to seal - and this seems to be my problem.

I ordered a new filter plug and two new fibre washers- however I also found a metal replacement washer pair on offer which are apparently reusable with care so I ordered two of those as well.

I



Nub of the problem old washer right- thinner than new (left) either from new or through over-compression. New washers were 2.6mm, the old ones 1.4 and so that's 2.4 mm of thread saved on the filter plug fitting

New filter plug in position with fibre washers.

The "metal washers" turned out to be two large Dowty washers with a gratifyingly thick rim. I havent fitted these as yet as the fibre ones arrived first but I may do so later.

It seemed churlish to have come this far and not checked the sump so I undid the 4 x 3/16 WW bolts holding it and allowed the oil to drain into a container.
sump retained by 4 x 3/16 bolts. Bit nasty and a couple of gouges.

Sump removed, lots of gunk trapped around the edge of the gauze and gasket 

Remove gasket - note crud around gauze and...

Clean up the filter mesh. I used my sonicating bath and it loosened the crud very nicely.
 The sump is obviously on the bottom of the motor and so the plate and the bolts are a prime candidates to collect grit- and I found quite a lot worked into the threads of both bolts and bolt holes. This will wear them in time so I cleaned all the bolts and washers in the sonicator and cleaned out the threaded holes in the crankcase with carb cleaner spray and a pipe cleaner
The underside of the plate had obviously been scraped at some point resulting in some grooves and ridges. I filed these as smooth as I could get them and then treated the sump plate to a new coat of VHT alloy effect paint. I refitted it with a fresh gasket, using copaslip on the bolts.

The rest of the reassembly went gratifyingly well: I used copper RTV silicone gasket to help seal the exhaust into the head. Even the problematic right footrest turned out to be no problem- it was a taper fit not a splined fit and after cleaning both tapers and the bolts it reassembled without play.

Wednesday, 9 March 2016

B25 head: Reconditioning valves, guides and thread repair

Valve Guide Installation:

In my original head the exhaust guide that I removed  was 0.502" in diameter, the inlet 0.500". Half inch appears to be the std size so the exhaust must have been changed at some stage. Both my new guides were 0.502 which is OK for the exhaust but presents a problem for the inlet. The general wisdom is that for brass guides in an alloy head, then the guide receiving holes in the head should be 1.5-2 thou smaller than the guides to achieve an interference fit. The exhaust guide is therefore fine but its likely that the hole for the inlet guide is too small for a 502 guide in this position. I should either get another (smaller) guide or enlarge the hole.

The installation tool is shown here, new valves are effectively both exhausts. I boiled the head again - I have an old dental sterliser that is just big enough, and put the guide in the freezer to maximise size compatibility and then installed the exhaust guide.
Installation tool consists of threaded shaft with conical head, 2 valve adapters and a shaft nut. There is also a hex wrench to hold the conical head as the nut is tightened.  The brass object here is the new guide. 
Conical head seated on the valve seat internally. Note hex key hole in the head to hold it whilst the draw nut is tightened.

The tool is assembled as shown; the conical head fits into the valve seat in the head with the thread projecting backwards. The guide is slipped over this and aligned in the hole in the head. An appropriate spacer is applied behind the new guide- one for flat ended guides and one for tapered. The tapered end of a tapered guide should slip inside the tapered counterbore of the adapter- in my case it didn't so I used the plain adapter. The final step is to tighten the nut down onto the shaft, holding the conical headpiece on the inside with the Allen key. As the nut is tightened the valve guide is drawn into the hole. Its properly seated when the flange abuts the head.


New guide in position. Note that in reality I had infilled the bolt holes already for thread repair (see below)
About this time I acquired a second B25 head. This one was also used  with very worn guides and although a couple of the rocker stud threads were stripped, the flange itself was  in good condition and could be re-threaded. I decided to eventually restore both heads and from now on some pictures may be of one or other head to illustrate the processes.


Fitting the inlet guide however, presented a problem. It is probable that it would fit simply as above, but the hole will be at least 2 thou too small and so carries the risk of cracking the head. I ordered a 0.5 inch reamer to enlarge the head hole to 500 thou. This should then give the required squeeze on a 0.502 guide if the reamer is sized that accurately. The reamer came and was surprisingly well sized- its shaft measured 500 thou dead on. I reamed the valve guide holes by hand allowing the reamer to pass right through once using plenty of cutting oil, rather than withdrawing it as they can cut again on the way out. This didn't remove much material but still resulted in a snug fit for the guides which were easily installed using the tool as above. I ordered two new guides in order to restore both heads.

New guides installed.
When fitting guides it is always possible that they do not line up in the exact same direction as the originals. This would mean that the seats are out of alignment and the valves wouldn't seal properly. Therefore when changing guides its necessary to recut the seats in alignment with the guide and this is done using a reseating tool.


I ordered a cheap set of valve seat recutters. As so many tools these days, they came from India- but hey I figure that they still manufacture the Royal Enfield and of course the Morris Oxford so they should understand imperial! This set has a wealth of different sized and angled cutters plus the handles and pilots so I reckoned that at about 20 quid it was really good value. Downside- it wont work on hardened seats used for unleaded- this would need carbide cutters which are dearer.

I selected a cutter that matches the valve and a 45 degree angle

The cutter is screwed onto the handle

The set comes with a set of imperial plots and one of these fits the BSA valves perfectly. The pilot screws into the cutter handle to hold the cutter parallel to the guide. It has to be done up tight as it mustn't wobble!


I used cutting oil on the cutter and grease on the pilot shaft, inserted it into the guide and rotated it to cut the seat again. 
The front seat has been recut already- the one at the back is shown here before recutting... juyst as an aside I did also clean up the plug hole threads with a chaser- they have come up very nicely too.

...and here after the recut. This second hand head was significantly marked inside which I think comes from decades of  using inappropriate decarbonising tools. Luckily they don't affect any of the sealing areas-either valves or barrel.
Reaming the guides
The fitting process causes the guides to pinch up and distort a little. These days its recommended to ream the guides when fitted to ensure that the valves operate smoothly. The exhaust guide usually requires a larger clearance as it runs hotter; about 2 thou clearance guide-to-stem is OK  and the inlet needs about 1 thou. The stems of these valves are made to different diameters and differ by 1 thou (exhaust is smaller)so that the same reamer can be used for both guides. Accordingly I also ordered a 5/16 reamer to ensure that the guides are parallel after fitting and to arrange the correct clearance; At 0.3125", this reamer is 0.0005 larger than the size required but its far cheaper than buying the absolutely correct 0.312 inch reamer.


5/16 reamer- use cutting oil- note I have cutting oil in the 3-in-one can, although I think that would work too.
 As before I reamed the guides by allowing the reamer to pass once right through each guide. This did give me more clearance in the exhaust than the inlet but both felt pretty smooth.

I ground in the valves, cleaned and refitted them with their springs- note re compressor arm position as above- it must not foul the rocker box flange.


A word about cleaning the head...

Throughout this the heads were fairly mucky- the second hand head was definitely the worst
Heavily carbonised second head
I cleaned these using aerosol EGR cleaner- diesel is best but I only had the petrol formulation. This can be swirled around the chamber in inside the ports and exhaust housing using a Dremell with a soft brass brush. It helps a lot if you have a flexible drive shaft as well.  When you clean the valve seats remember to move only in a circumferential direction- just in case you generate scratches. You don't want those running across the valve seat where they might bridge the seal. Its not so important in this case as I was going to recut the seats anyway. On the B25 the barrel is spigotted into the head meaning that there is a recess around the chamber in the head and a ring projecting above the barrel that fits into it. Obviously these need to be able to fit closely so its important to remove any carbon from around these structures as well.


Inside exhaust housing cleans up nicely

As does the head and ports, note spigot recess also cleaned out.

Last stage was to clean up the gasket face using a Ro-Loc bristle brush (yellow grade) in a hand drill
This is the second - replacement head  that I bought and its renovation as shown here is complete (stud thread repair details are below)
Rocker mounting flange also cleaned up.


Thread Repair
Chronologically I was repairing the threads at the same time as fitting the guides- and had completed this before I fitted the valves, but it seems to make more sense to explain the process of sorting out valves and guides completely before I addressed the repair of the threads. Apologies if this causes confusion...


A note about threads.
BSA (and Triumph for that matter) have used a multiplicity of thread sizes over the years and although some understand it- I certainly don't. What I have gleaned is this: Studs in particular tend to have one end in alloy and the other in a steel nut. The threads used on these ends are often different  (at least in early bikes) partly because of the different strengths of these materials and the fact that studs aren't removed as often as nuts, but perhaps most importantly, that they grip in different ways: Nuts tighten through torque twisting onto the threads (which pulls the nut down and the stud up). Studs are fitted into the head at a much lower torque and grip largely through the pulling action of the nuts rather than a turning force. Alloy in particular can strip easily if you overtighten (twist) a stud or bolt. For these reasons BSA tended to use a coarser pitch in alloy than in steel. In this case I am particularly interested in the 1/4 inch studs fastening the rocker box onto the head.

Pre-unit bikes used a Whitworth thread in alloy and a cycle thread BSC (aka CEI) into the steel nut. For the 1/4 studs at least the ww was 20 tpi and the BSC 26 tpi. With unit construction the WW was superceded by BSF threads. This is also 26 tpi but the angle of the thread peaks between the grooves is different, presumably this improves resilience in alloy (maybe ?). After 1968 BSA moved to UNC threads for both ends of these studs (so did it ever matter?). For my bike this means that I should have UNC threads... but I don't! I seem to have BSF on the lower end of the stud and BSC on the top, both 26 tpi which I suppose is to be expected for a bike made after 68, but according to a design that's much older. Since these threads are of equal pitch they will mate and a BSC stud will screw into a BSF hole and vice versa. However the thread cut is likely to be distorted if you do this. Given that they must have been loosened several times over the 50-year life of the bike (and some have even been put back the wrong way round) it is clear that the differences between these ends are now hard to detect and most of the threaded holes in the head are loosened- some stripped out. However if I am re-threading the head and fitting any new studs then I'd like to get it right.

The first point is what way up should the studs be? Mine have been mixed up. Examining the studs showed that the threaded lengths are different at each end: The shorter end I think is intended to go into the head since the alloy flange to which the rocker will fit is not very deep, and longer threads would screw right through. Consequently this end should be BSF. For some of the studs this thread length difference isn't so clear because they screw more deeply into the head than those on the flange.

Thread Repair.
Threads with minor damage can be restored by chasing with a tap or die. If you are unsure which thread is which then the recommendation seems to be:

  • For Studs; use a BSC die first and check fit. If its tight chase it through with a BSF die.
  • For Holes; Use a BSF tap first and check, if its still tight chase it through with a BSC tap.

Using the threading tools in this way cuts the smallest amount of metal in the first pass in each case, after all you can always  take more off but can't put any back!

Threads with major damage are more tricky and there are three ways of fixing them:

1. Re-thread: 1/4 inch is actually very close to M6, and M6 studs are easily bought. If you aren't worried about originality then this might work but I suspect stripped threads will already be enlarged past this approach. If this doesn't work then you can drill out and re-thread the hole at a bigger size. M7 could be used at a pinch and is common for studs on many moped cylinders (Zundapp), some may be about the right length? M8 is likely to be way too big.  Even M7 though does mean that the stud will be larger, which may mean that either the component into which it fits may need modification- or a one-off special stud has to be made with different diameters at each end. This sort of approach is the only one I have tried to date.

2. Clean the hole, fill it with aluminium weld, re-drill and tap to original size. Sadly, TIG welding is quite an art, and since I have neither equipment nor experience this isn't practical for me. However, aluminium repair rods are available, and if these work then it would be a really useful process to acquire. The repair rods are self fluxing and can be fitted with a brazing torch. They come in 2 grades with melting points 300 or 400 degrees centigrade. However, as aluminium doesnt melt until around 660deg, the rods arent likely to merge with the originsal material. The higher melting point rod is recommended for stressed areas like threads.

3. Drill out the hole, tap and re-thread to the original size using a helical insert such as helicoil or V-coil. These are available in a variety of sizes imperial and metric, but they are expensive. Metric versions can be cheaper and so going metric might be a good idea cost-wise if you can get M6 studs of appropriate lengths.

I would like to stay original so option "1" isn't a solution this time. I do have equipment to take option "2"; it is cheaper than a coil insert and doesn't enlarge the hole. Lastly, Even if its a total failure then option "3" would still be available to enlarge the hole and use a coil. Accordingly I'm going to try the aluminium repair rod first.

I decided to try to repair the original head using the aluminum repair rod approach, and the second head using helicoils.
Using Aluminium repair rods.
I obtained both types of rod from eBay- AL300 and AL400. To prepare the head I washed it extensively in degreasant and then boiled the head to lift as much contamination off the metal as possible. This also puts a lot of heat into the head and should help to reach the repair temperature.
The rule for using this material is that it will melt into the existing aluminum but only if the existing metal is hot enough. The repair rod must melt on contact with the hot metal not the flame!

Success was mixed: Firstly, I couldn't get the head hot enough to melt the AL400. This might be because I was using a butane cartridge in the torch, I believe a butane/propane mix will give a hotter flame. The other problem is that aluminium simply conducts the heat away from the flame point very efficiently, after all this is exactly what the head is designed to do! Perhaps I should be more patient?
Thread repair head 1- using Al300/Al400 rods

I used a piece of steel wedged below the flange to block off the hole.
Infill with repair rod
File smooth and repair second hole
Heating the steel and alloy turned this hole into a tiny crucible. The repair rod didn't so much melt as break off and then melt. AL400 didn't melt efficiently (see above) so I used the AL300. I am hoping that as this is a stud that will be "loctited" in and not removed frequently, the 300 may yet prove to be strong enough. Its certainly easier to use. I was able to fill the hole with molten material, using the flame to heat the top of the pool of weld at the end to help smooth it down. When cool and solid, both top and bottom of the weld projected above the surrounding metal. I filed these carefully flush, trying not to mark the gasket mating faces. This resulted in a repair which can now be re-drilled for tapping at 1/4 BSF. Its necessary to refit the rocker box to be sure that the holes will align.
 wa
Rocker box in position, I then marked the position of the hole needed by passing a closefitting drill through the hole using the pillar drill and drilling just enough to mark the position needed..
I marked the holes using a close fitting drill passing through the rocker box. Once the position was marked I could remove the rocker cover and drill the holes in the pillar drill using the tapping drill that came with the BSF taps. The hole I had filled with Al400 simply cracked out as if it had never been filled- confirming my fears that the rod hadn't melted properly. The AL300 repair drilled very nicely... and tapped easily

I tapped the hole using a 1/4 BSF tap

Result wasn't at all bad! It certainly took the studs well.
I refilled the other hole and repeated the process to repair that thread as well. I don't think that these rods are really going to be suitable for building up the flange where the piece has cracked away. I had hoped that this might be possible but I no longer believe this will be so*. This might need a visit to a TIG expert!

*- I did try! No luck!!

The TIG experience!
I sent my original head (head 1) off to a professional welder to build up the area around the missing flange with weld. The head was returned with a great big irregular lump of aluminium welded on.



This was at least easily machined so with a combination of hand filing and disc cutting I was able to restore a reasonably good profile, flush with the gasket face of the rocker flange.


I have found in this job that getting the threads drilled cleanly and accurately is key to getting the rocker box to sit well on the head- some of the holes I had drilled earlier weren't exactly right and the box was stiff to fit. I recommend therefore that whenever possible you actually drill the holes with the box in situ rather than just marking them and then removing it,. To my surprise the 1/4 inch tapping drill- and even the tap fitted nicely trough the rocker box and allowed me to drill an accurately positioned hole and tap it vertically.


Tapping drill and 1/4" tap fitted through the rocker box- drill in situ and start the tap as well.

New hole drilled and tapped.
I would recommend this approach whenever you can- sadly for some of the longer studs it wouldn't be possible unless you get a longer drill bit and tap!

Having sorted this hole I was then able to ream the guides, re-cut the valve seats and decarbonise the chamber and ports completing the renovation of this head.

Helicoil (V-coil repair)

I decided to try a helicoil repair using the second head.

V-coil kit, drill, tap, insertion and tang breaking tool plus several inserts at 1/4 BSF


Step 1- drill out the holes taking care to be on target and vertical- clamping the head firmly helps accuracy
Step 2 Tap the hole using a hand tap handle and plenty of cutting oil, I used a pillar drill to steady the tap (turning by hand!) simply to make sure it was vertical.


Guide coil with a finger as it starts to screw in.


Thread in the helicoil insert to just below surface of the alloy using the insertion tool- pass it through the helix and engage the tang at the bottom. Position the coil above the threaded hole using your fingers and start it carefully into the thread. Screw in evenly and gently, do not reverse motion or the tang will probably break off.


Break off the tang using the tool.- its quite straightforward, just place the tool on the tang and give a sharp knock downwards. As these are through holes the tang simply drops out.
Tang break off tool

I repaired two holes like this before removing both valve guides as above. Both were a great success! Helicoil is a really neat solution to this problem, it costs more but its quick, simple and effective.  I test fitted the studs which all screwed in nicely although I think all will need Loctite threadseal.Once the threads were fixed I was able to complete the renovation of head 2 as described above.  I now have both finished and need to sort out which one to use.