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Friday, February 15, 2013

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             charles
                                             

Friday, February 8, 2013

Porting the Chinese 48cc HT engine

this information is really cool, is from http://www.dragonfly75.com/:

I use Jaaps Puch calculator (in Dutch which is downloadable to your Windows computer) after measuring port heights, or use a degree wheel to figure out the port timings in degrees. Go to the bottom of this page for the translations to English if you want to use the Puch Calculator. Or click here to go to a good on-line calculator. (Use 38 for stroke, 85 for conrod, .8 for "deck").

There's two ways to describe the port timing of each port. One, the most common, is to describe the total amount of crank degrees the port is open during one crank rotation. The second way is to tell at what crank degrees, in relation to zero degrees (piston top dead center), the port begins to open. From top dead center to bottom dead center, one half rotation, is 180 degrees. So if the exhaust port opens at 110 ATDC (after top dead center) then to get the total open port duration you'd subtract 110 from 180 and multiply by two. So 180-110=70. 70x2=140. 110°ATDC is 140° duration. If the intake port of a piston port engine (like the Grubee) opens around 60°BTDC (before top dead center) then you can figure the duration just by multiplying by two. That would equal 120° duration. For changing any port, more duration is for higher rpm power and less duration befits lower rpm power.

Standard 48cc : 141° exhaust duration (28mm from top of cylinder), 111° transfer duration (32mm), 112° intake duration (55.5mm), 44.8mm piston length at intake side, .8mm deck height, 38mm stroke.
Except for the intake timing this engine is ported good for a mild low rpm power. An ideal intake timing for the standard engine is 60° BTDC (120° dur.). To get 60° just lower the bottom of the intake port to 56.7mm from the top of the cylinder (or remove 1.2mm from the bottom of the intake side of the piston skirt). Also widen the port by 4mm on each side. (See explanation later on page.) If you need more speed you can change the rear sprocket to one with less teeth or raise the exhaust port. A 10% decrease in number of teeth will result in a 10% increase in speed. But this change reduces your ability to accelerate and climb streets.
Here's how you can change the ports of the engine if you want the best all around power from it. If you don´t make .8mm piston ramps for even more low rpm power then make the distance to the transfers 31.2mm. These dimensions have been scientifically calculated to be the best for a top rpm of 7000. 
Don't port for higher rpm's unless you plan to also balance the crank. Otherwise the engine will be annoyingly vibrating above 5000 rpm and will destroy the con-rod and crank main bearings quickly. This is especially important for the larger 66/80cc engines which use a similar crank with a heavier piston that imbalances it even more.
Here is porting for the best low rpm power. It's basically the same as stock except for more intake duration and wider ports. Raise the exhaust port for more top speed if desired.
Porting can be done at home with a rotary tool that uses the common 1/8" diameter shank bits. WalMart sells a good one with 3 speeds and 1" diameter cutting wheels which can be trimmed down to smaller diameters as need be. Just be sure to not have your eyes in the path of metal bits being thrown outward away from the wheel. Accurate measurement of port heights can be done with a digital caliper, also from WalMart.
Exhaust port enlarging:
According to a free pipe design program, for low rpm power with an expansion chamber the exhaust port area needs to be no more than an equivalent 17.8mm circular diameter to match the 20mm diameter of the exhaust pipe at a 1/1.125 ratio. That means the port should be no more than 12mm high and 24mm wide (measuring with something straight from left to right edge). Raising the port ceiling 1mm from stock and widening it slightly will result in this dimension. Top to bottom port height is equal to 38.7 minus the # of millimeters the port is from the top of the cylinder. That will result in less than the measured amount because the piston doesn't quite go down to the bottom of the port. Mine, at 12x24mm, is equal to that 17.8mm diameter. Expertssay the port should not exceed 70 degrees. That equates to 24.5mm for a 48cc, and 28.1mm for a 66cc. (Those widths are not straight line, but rather the port width on paper impressed with the port edges.) Click here to read more about port shape and port timing.
Transfer ports timing:
Stock is 124.5° ATDC (111
° duration) which shouldn´t be increased unless the exhaust port timing is also increased. Here is some info if you want to change its height but don´t have a digital caliper: The transfer port distance to top of cylinder is hard to read using a ruler since it's kinda in the middle of the cylinder. So I would mark the piston with the transfer distance I wanted by measuring from the bottom of the piston. Then I inserted the piston bottom end first into the cylinder from the top. Holding the piston so that the mark is equal to the top of the cylinder I could see the difference between the port height and the bottom edge of the piston skirt in order to know how much metal I needed to dremel off to raise the transfers to where I wanted them. The area to be dremeled off can be marked with a black felt tip pen.
Lowering intake port:
Stock intake distance from top of cylinder to bottom of intake port on the 48cc HT is 55.5mm (56.1° BTDC). I first lowered my intake to 57mm (60.9° BTDC) and it had good grunt (relatively speaking) and started and idled good. I then lowered my HT's intake port to 58.5mm (65.5° BTDC) and squared it off more so that it had less of a curve to it. The bike did not want to start and had no low rpm power at all. It was embarrassing having to pedal so much to get it going. It did better at the highest rpms though and gained 1mph top speed. So unless you are porting for a screamer then I don't advise going lower than 57mm. I fixed it by putting JB Weld at the bottom of the intake port to bring it back up to 56.3mm (59°BTDC) which returned the needed low-rpm torque to the engine. Look at the graph below showing the air/fuel delivery ratio change with intake timing change on a 150cc engine. A period of 118° (59° BTDC) and 125° (62.5° BTDC) gave the best results (and anything between these two).

Higher Compression
(This section has its own page now. click here)
Expansion chambers: A pipe designed for use with this engine should have a broad powerband and increase top rpm power. Unfortunately most all pipes sold for the Grubee engine are made for pocketbike racers and have a narrow racing powerband (as evidenced by the 12 degree or more baffle angle whereas motocross pipes only have a 10 degree angle). If you want it for having fun then that is fine but for street use there are no pipes available that are suitable other than making your own torque pipe. Click here to read about it. Of course you can buy a racing pipe and make it into a decent pipe by cutting the baffle in half and installing a 2" long cylinder to reduce and lengthen the baffle return wave. Most people think that the distance of the header pipe is just a matter of taste but I want you to know that you shouldn't buy an expansion chamber unless you are willing to go to the trouble to test different lengths until you find the right one to give you the best top speed.
Using a better carb will enhance power all thru the rpm range if it is jetted right. Don't buy a carb larger than 16mm unless you port for high rpm's. If you stick with the stock carb then be sure to throw away the trashy HT intake filter and put a good performance filter on it for less intake restriction and more engine protection. I tested the 12mm Dellorto against the 14mm stock NT carb and got more low end grunt and top speed using the Dellorto (because of better mixing) even though it was smaller.
Using better piston/rings is advised because the standard piston has rings that allow too much ring end gap and wear the cylinder down faster with their 2mm thick rings. Both of the following listed piston/rings are available from www.treatland.tv and the Honda piston is 1mm taller from the wrist pin so that it gives a strong compression boost without having to mill the head and discard the head gasket. The Yamaha piston has the same pin-to-top height that the standard piston has. With the Honda piston you may need to dremel the edges of the heads combustion area to allow .8mm distance between it and the piston at TDC. 
Honda Hobbit 40mm piston $30
51mm from crown to bottom of piston
26mm from wrist pin center to top edge of piston
10mm wrist pin diameter
1.5mm ring vertical thickness

Yamaha QT50 40mm piston $85
wrist pin size = 10mm, distance from top (not including crown) to center of wrist pin opening = 25mm, total length (not including crown) = 47mm, 1.5mm ring vertical thickness
A great read: Go to Micro Car Project and click onto Port_Timing_Alteration and Other_Solutions on the left hand sidebar.
from http://www.mopedarmy.com/wiki/Puch_cylinder_kit_summary
(Make booster port equal to or 7° before transfer port opening (2mm higher).
Maximum exhaust port width is 70-72% of cylinder diameter.)
Calculate 2 stroke engine displacement:http://www.everything2stroke.com/resource/displace.php
Below are some examples of port timing from various minis:
Metrakit 65cc (43.5mm stroke) torquey. PORT MAP:http://i136.photobucket.com/albums/q194/flip27foto/PuchMaxi/naamloos.jpg
2 Transfer Ports 123° ATDC (153
° duration)
Exhaust port 103.5° ATDC (114° duration)
Blowdown: 19.5°
Eurocilindro/Athena 70cc (45mm)  reed-valved fast+torquey
# Intake port (variable): Raised intake as booster-port
# Transfer Ports 118.6° (122.75° open): 4 ports + 1 wide booster
# Exhaust port 97.5° (165° open): Oval
# Blowdown: 21°
RGD/TCCD 70cc (45mm)
http://img201.imageshack.us/img201/1639/rgd70ccfi4.jpg
# Intake port 63.5° BTDC: oval
# Transfer Ports 119.5° ATDC: 4
# Boost ports 123°: 2
# Exhaust port 98° : oval
# Blowdown: 21.5°
Malossi 60cc (42mm)
# Intake port 61° BTDC (122° open): oval
# Transfer Ports 125° ATDC (110° open): 2
# Boost ports 135° (90° open): 2
# Exhaust port 100.5° (159° open): oval
# Diameter exhaust port: 25mm
# Blowdown: 24.5°
Polini 65cc (43,5mm) torquey reed-valve intake engine
# Intake port (variable): 7 including 3 boosters 123° BTDC (114° open)
# Tranfer Ports 123° (114° open): 4 ports
# Exhaust port 89° (164°): oval
# Blowdown: 25°
Airsal 70cc (45mm) "perfect timed cylinder"http://img144.imageshack.us/img144/3323/airsal70cc2vf7.jpg
# Intake port 68° BTDC (138° open): oval
# Transfer Ports 123° ATDC (114° open): 2
# Boost ports 123° (114° open): 2
# Exhaust port 86° (170° open): oval
# Blowdown: 28°
Jaaps Puch calculator 

Click the button at the variable you want to calculate and fill in all other fields.
    Spoel-/uitlaattiming = Transfer or Exhaust timing
    Timing: (total degrees port is open. Divide by 2 and subtract from 180 to get degrees ATDC)
    Poorthoogte: Port height (mm of port from top of cylinder)
    Deck: (mm from piston top to cylinder top at TDC. .8mm for my HT)
    Slag: Stroke (of piston=38mm for HT)
    Drijfstanglengte: Connecting rod length (85mm for HT)
    Inlaattiming = Intake timing
    Timing: (total degrees port is open. Divide by 2 for degrees BTDC)
    Inlaathoogte: Intake height (in mm from top of cylinder to bottom of intake port)
    Zuigerlengte: Piston length (at the intake side, 44.8 for HT)
    Deck: (mm from piston edge to cylinder top at TDC. .8mm for my HT)
    Slag: Stroke (38mm for HT)
    Drijfstanglengte: Connecting rod length (85mm for HT)
   
    Snelheid, toeren = Speed, rpm
    Snelheid: speed in km/hr (convert to mph athttp://www.sciencemadesimple.net/speed.php )
    Toeren: rpm
    Voortandwiel: front sprocket teeth (10 for HT)
    Achtertandwiel: rear sprocket teeth (44 for stock HT)
    Interne verhouding: primary gear reduction ratio (4.1 on the HT)
    Omtrek: outer circumference of driven wheel (2.133 for 26x2.125" tire)

How to Balance the Engine for Less Vibration and More Top RPM

this is from http://www.dragonfly75.com super cool information

The fix is two-fold. The first half of the fix affects vibration all through the rpm range. The second half of the fix lessens vibration only at the top rpm range where it is caused by the standard too-advanced ignition timing.
1. After you have settled on an appropriate cylinder compression (in psi. more compression gives more power) then you can change the port timing just a bit for better high rpm power and balance the engine by removing weight from the piston and wrist pin. (Drilling holes in the flywheels only offsets the weight of the piston and wrist pin.) On bikes that self-limit their mph by vibration you can easily tell if you are making it better (more in balance) by the max velocity. The first part of the fix is to lighten the combo of piston and wrist pin. I had my wrist pin drilled out from a 5.8mm diameter hole to a 7.5mm hole. With these weak engines there is no need to worry that the pin will be too weak after drilling. The same holds true for the piston. Your machinist can use a 9/32" (7.1mm) carbide drill bit to use in his lathe on the wrist pin (available for $8 from Grainger) or you can buy a wrist pin for the 48cc piston that already has a 7.5mm hole in it, available from Treatland. Next are 11gm wrist pins with a 7mm hole (1.2mm more than stock) from pocketbikeparts.com that will work in the piston for a 55cc or 60cc Grubee engine:
Generic 36mm x 10mm wrist pin & bearing $13
Generic 36mm x 10mm wrist pin $9
They probably also work in a 69cc engine since the piston is only 2mm wider. Also available is a 37.5mm long 10mm diameter titanium wrist pin (6.3mm I.D.) which is really good since titanium has around 58% the weight of stainless steel and is very strong. You can use a grinding wheel to shorten it if needed. It is 3 grams lighter than the 55cc/60cc wrist pins.
You can also lighten the piston by drilling holes in it that will be no more than 5mm from the side edges of the exhaust and intake port. Drill size is 9/32" and each hole shouldn't be closer than 10mm center-to-center from the next hole. Here's a photo showing where you can drill up to 9 holes on each side. Unfortunately, if the piston wall is 1.9mm thick (as mine is), only 18 holes will remove only 3.3 grams.
I have a reed valved engine and with the additional holes on the intake side mine totaled 27 holes and I have rev'd it to 37mph (8400 rpm) and it held up OK. Use an exacto knife to trim the outer edge of each hole to not be a sharp edge. I used a small bit with my dremel to grind a dent in the piston where each hole should be drilled. Then I used a small drill bit to make the pilot holes. (Otherwise the drill bit would wander off center.) Then I used the 7/32" bit to make the final size. Aluminum is very light so even 18 holes won't make a huge difference in weight but when it comes to engine balancing every little bit counts. Once you find the best balance you can change the porting a bit. With these two changes the vibration should be much less and the top rpm much more.
2. The second part of the fix is to buy the Jaguar CDI which is designed to spark later at rpm above 3600 to lessen the combustion/compression forces that the piston and flywheel have to push against. This approach is standard with 2 stroke engines. I think the CDI that comes with these engines is made for a 4 stroke since it does not have that essential change in timing at high rpm. That causes reduced power and reduced rpm, both of which are wanted by the company so that it can pass all countries regulations. But you don't want that because you want power and a bit more rpm without having to endure excess vibrations at the handgrips and seat.
Here's a quote from Crankshaft Design, Materials, Loads and Manufacturing, by EPI Inc.
"Combustion forces and piston acceleration are the main source of external vibration produced by an engine. They must be counteracted by the implementation of the crankshaft counterweights." [A counterweight essentially exists opposite the rod pivot by the removal of metal near the connecting rod pivot on the flywheels]

The graph here shows what I want to explain about engine balancing. The increase in centrifugal force from the imbalanced flywheels and the up/down upper piston assembly inertia (as it changes direction) is exponential with rpm. But the combustion/dynamic-compression force varies with rpm mostly due to spark ignition timing.The flywheel counterbalance (created by holes near the conrod pin) has to keep the total balance not too far from true at peak combustion/compression and at peak rpm when the combustion/compression is sharply dropping off due to spark retard.


Vibration is reported to be much more with the 69cc (80cc) engine and so this cure is even more vital for it. If not enough then you have to balance the crankshaft. Here are some reports on the motoredbike forum:
"Is the 2 cycle [69cc] motor known for a lot of vibration? I have some rubber pads between the mounts and the frame, but anything over about 15mph is just about unbearable."   post

"My seat seems to be vibrating a little too much to comfortably ride long distances at full throttle. It seems to have gotten worse recently. Any idea how I could figure out where it is coming from? The engine mounts are solid I wrapped the frame in thick leather under the mounting hardware. I'm running the Chinese 66cc 2 stroke on a mountain bike."  post

"I just finished my first motored bike build- a "Black Stallion" 66/80cc from Kings Motor Bikes. ...at the end of yesterdays ride I cranked it wide open to see what it could do. As it built RPMs, it passed a certain range and the entire bike began vibrating like the engine was totally mis-balanced! The gas tank loosened and shifted, and I had trouble keeping my hands on the handlebars! I dropped RPMs, and the vibration went completely away. I tried doing this several times, and each time I crossed that certain RPM barrier, the bike would go into wild vibration!" post

"I have a huffy panama jack bicycle, with a 80cc engine on it. I have such a bad vibration in the bike, its terrible.Ive tried rubber motor mounts, does anyone have any ideas? please help!!!!!!!!!!!!"  post


Crankshaft balancing (for even less vibration):

An imbalance in the crankshaft in relation to the reciprocating weight of the upper end causes vibration and a loss of power. Making sure your engine is balanced correctly is essential, especially if you are modifying the engine to work in a different rpm range than what it was designed for. Using a lighter wrist pin lightens the balance area by 4.5 grams which is enough to balance the crankshaft in a stock 48cc. If it has higher compression and is ported for higher revs then the Jaguar CDI will be needed.
There is an old fashioned way of balancing the crank, with more weight removed from the counter-balance area for higher rpm. But in studying the subject I see that the main two forces that need to be counter balanced are changed in value of force equally as rpm increases so that rpm is not a factor. That means that the counter-balance mostly depends on the upper assembly weight and dynamic cylinder pressure, not on rpm. Cylinder pressure changes non-linearly with rpm, mostly due to ignition timing. On my bike with the ignition timing curve of the Jaguar CDI it has the most cylinder pressure at around 6750 rpm.
I have two different 55cc engines using different cylinders and pistons. One is with piston port intake and the other is reed valved. The results I got testing those, along with online calculators for upper piston assembly inertia force and the centrifugal force of the counter balance is what I base my theory of balancing on. The piston port engine was way off in balance, and the other was perfectly balanced. Using it as a base point I know I have to use 61% of the conrod weight as its contribution to the upper assembly weight. And I use the downward piston force instead of the upward force (which is more due to more piston speed going upward) or the average force. The increase in piston inertia force going upwards is offset by an unknowable amount of cylinder pressure which is why I don't use it.
1st test:
Piston port intake 55cc engine (see engine details below) ported for 10,000 rpm but that achieved only 9100 since I just did the test runs with the standard exhaust pipe instead of an expansion chamber with the correct header length for 10,000 rpm. Anyway here are the details:
upper assembly weight: 122gm
additional counter balance weight removed: 9.8gm
The engine vibrated between 5600 and 7900 rpm and ran smooth before and after that rpm range.

55cc high rpm piston port intake engine:
55cc Grubee cylinder/head on 48cc bottom end
port durations: 185 exhaust, 119 transfers, 125 intake
transfer port walls removed for greater transfer area
stuffed crankcase
155 psi cranking pressure
18mm Mikuni
custom intake manifold
piston port intake
slant plug head with squish band .65mm from piston
Kawasaki KX65 piston and rings (adapted for use with piston port intake)
Jaguar CDI with Kawasaki KX high voltage coil
44 tooth rear sprocket
26" wheels with mountain bike tires
peak head temperature: 425F
2nd test:
My other 55cc engine (reed valve, Honda piston, torque pipe, 18mm Mikuni) with 77.3gm upper assembly with 15.8 grams removed via a 9.15mm diameter hole thru both flywheels allowed my engine to go up to 9150 rpm (downhill) without any bothersome vibration.

Here are the force evaluations of the two engines at 4000 rpm:
Upper assembly weight (piston, wrist pin, bearing, 61% of conrod):
piston port engine: 134.5 grams
reed valved engine: 120.5 grams
Downward assembly inertia force at 4000 rpm:
piston port engine: 78.45
reed valve engine: 68.7
Centrifugal force of counterbalance*:
piston port engine: 60.2
reed valve engine: 68.7  

Centrifugal force divided by Downward force:
piston port engine: .767
reed valve engine: 1.00 

*In figuring the counter balance weight you have to include everything that would affect it. As example: my flywheel came with two 11.5mm diameter holes through both flywheels. The stainless steel there removed adds up to 50 grams. The conrod pin added 3.3 grams after the weight of the conrod pin holes weight were subtracted from it. The part of the conrod that is around the bearing, and the bearing itself, weigh around 30 grams. The centrifugal force has to be figured at the two distances of 19mm of the conrod, and 36mm of the counter balance holes.

Now we can calculate the needed "missing" balance weight for the 48cc Grubee engine. What I first noticed is that the existing balance holes are not the same distance from the center of the crankshaft as the connecting rod pin is. That is important because the farther a weight is from the centerpoint the more centrifugal force it has for the same rpm. Using a test weight of 1kg at this site I see that at the 36mm distance of the balance holes gives 1.9 times the centrifugal force as 1kg at the 19mm distance of the conrod pin. 

Upper Assembly weight and downward inertia: 61% of the conrod is 43.5 grams and the piston assembly weighs 79 grams for a total of 122.5 grams. That weight at 4000 rpm (with 1.5" stroke and 3.35" conrod length) gives 71.45 pounds inertia force.
Counter balance weight and centrifugal force: The two factory-placed holes of 11.5mm diameter equate to 50 grams of missing weight which gives 71 pound-feet of centrifugal force at 4000 rpm (at 36mm radius). 30 grams of conrod bearing and "end" added to the 3.3 grams of the extra conrod pin weight gives 33.3 grams which gives 25 pound-feet of centrifugal force at 4000 rpm (at 19mm radius). 71 minus 25 equals 46 pound-feet.
Centrifugal Force to Downward Inertia Force Ratio: 46/71.45= .64 which is terrible. 
Calculating needed counter balance weight removal: 71.45 - 46 = 25.45 pounds of force which requires 43.7 grams weight removal at the same 36mm distance as the existing holes. A 10mm diameter hole drilled through both flywheels will result in 41.5 grams removal according to this site (be sure tomultiply the resultant weight of kg by 1000 to get grams). But usually holes drilled are not perfect and so you can add about .15mm to the size. And so a 10.15mm hole will remove 42.8 grams which is close enough. A good quality drill bit of an equivalent 25/64" size is available for $16 online from Grainger. You can drill the hole yourself with an electric drill but it is hard and slow going. Best to do it at the machine shop.
piston inertia calculator
steel weight calculator
Since upper assembly inertia and flywheel centrifugal force stay neck and neck thru the whole rpm range then it is just the changing compression/combustion force that varies with rpm. That is influenced by cranking compression and ignition timing. My balanced engine has 165 lbs cranking compression. High compression and advanced ignition are typical of enduro bikes, not racers. Race bikes have lower compression (typically 9:1) and retarded ignition. So my engine, being like an enduro bike, is just right with a 1/1force ratio. A race  bike may need only .95/1 as a force ratio.
Here is a picture of my crank assembly with an additional balancing hole just above the conrod pin. The 6 blue holes are lightening holes for better acceleration (although I wouldn't recommend any more than 4 if the bike is for street use). The blue is foam filling half the hole. The ends of each hole were later filled with JBWeld. I used foam just to reduce the amount of expensive JBWeld used. The conrod hole and two factory balance holes are already filled with JBWeld for increased crankcase compression.
For the "80cc" engine, with a piston assembly of 107.6 grams and 11.15mm  counterbalance holes at 36mm from shaft center I figure a 12.6mm extra hole is needed to balance the engine. (drill bit)
Concerning determining the weight of the lower conrod bearing and the part of the conrod that is around the bearing: I figured that by dipping the two into a measured amount of water and seeing how many cc (ml) they raise the water level. My 48cc had an equivalent 30 grams.