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The 2025 Ducati Scrambler 10° Anniversario Rizoma Edition has been revealed to celebrate the Scrambler’s 10th anniversary. Only 500 will be made.

Based on the recently launched second generation Scrambler launched in 2023, the Scrambler Anniversario Rizoma Edition shares some of the recently launched Full Throttle’s components, but with several differences.

Rizoma creative designer Fabrizio Rigolio said: “This Scrambler is different from the others. It is dedicated to the 500 who dare, who see beyond, who wants to leave an indelible mark.

The colourway for this bike, defined by Rizoma in collaboration with the Centre Stile Ducati, is based on the chromatic balance of Stone White, black and Metal Rose.

Andrea Ferraresi, Director of Strategy and Centro Stile Ducati, added: “Rizoma has succeeded in the difficult task of reinterpreting Scrambler while maintaining its essence unchanged.

“I was struck by the formal rigour, the attention to detail and the cleanliness of the treatment, including the colour, that Rizoma has incorporated in the concept that then became this celebratory version of the tenth anniversary of Scrambler.”

The 2025 Ducati Scrambler 10° Anniversario Rizoma Edition is priced at £13,095 (RM73,425.89) in the UK.

Yamaha made big waves back in 2009 when they introduced the YZF-R1 of that year with a “crossplane engine.” It is also known as the CP4 in short for “crossplane four cylinder.” Yes, it has been 15 years already, yet there still exists some confusion on what it actually means.

Not helping to clear the air is Yamaha calling their parallel-twin CP2 (MT-07, Tenere 700, and YZF-R7) and their triple CP3 (MT-09, Tracer/Tracer GT, YZF-R9).

So, let us take a closer look as to what a “crossplane engine” actually means.

Let us start with the “flat plane” engine

The “plane” in the word alludes to the crankshaft’s throws i.e. how the crankpins are arranged. Crankpins are the cylindrical extrusions on a crankshaft where big end of a connecting rod (conrod) is mounted. On the top of this conrod is a smaller end where a piston is attached via a wrist pin. As such, combustion pressure pushes down on the crown (top) of the piston, forcing the piston down. This motion is carried by conrod to push the crankshaft, making the later go around. The rotation of the crankshaft is what gives the engine its torque and power.

Traditionally, inline-four engines have their crankpins arranged in 180° intervals between them. In other words, piston one is up, the piston two is down, the following piston three is also down, and finally the last piston four is up. Seen from one end of the crankshaft, all the crankpins appear one a single plane (axis), hence the engine is known as a “flat plane.”

In accordance to this, the engine’s firing order (the order which a spark is introduced to ignite the fuel/air mixture) is every 180° of crank rotation i.e. 720°/4 cylinders = 180°. Why 720°? That is because a four-stroke engine requires two crankshaft rotations (720°) to complete the four strokes i.e. intake, compression, combustion, exhaust.

To illustrate this: Cylinder one fires, the crank turns 180°, cylinder three fires, the crank turns another 180°, cylinder four fires, and finally, cylinder two fires after another 180°. This is called an even firing order since it is 180°-180°-180°-180°.

With this crankshaft structure all 4 pistons generate the secondary force in the same direction at the same time. 2 pistons move from TDC towards 90° and 2 other pistons move from BDC to 270°. It results in accumulating all the forces, because all forces are directed in one and the same direction. This is the total secondary force of this 180°crankshaft structure.

In other words, the inline-four engine has a lot of vibration but it only feels smooth because the shakes are quelled by a counterbalancer shaft.

Now the “crossplane engine”

The first crossplane crankshat/engine was actually first proposed in 1915, before Cadillac introduced the first crossplane V8 in 1923. V8 engines used flat-plane cranks prior to that.

Now, since we have illustrated the flat-plane crank, the crossplane crank has its crankpins offset by 90°. This means, while crankpin one fully up, crankpin two is 90° away. The last crankpin is 180° from crankpin one, thus crankpin three is 90° away from crankpin four.

This arrangement would give the engine a 90°-90°-90°-90° firing order but(!) it results in a very wild power delivery like the traditional 500cc two-stroke (albeit V4) GP bikes. Mick Doohan called this the “Screamer” engine.

So, to quell that kind of character, the Big Bang firing order was introduced in the 1990 Honda NSR500, which crowded all the four cylinders’ firing order closer together, while leaving the crankshaft to turn the rest of the way without power pulses.

This is especially useful for high-powered motorcycles, because power pulses will disrupt the tyre’s grip. Each power pulse “kicks” the tyre and if the rear tyre starts to lose grip and spin, the power pulses will keep it spinning, hence losing grip. The rider has two choices here: Roll out of the throttle or end up having less acceleration off a corner, and even crash. In today’s world, traction control will interfere to cut the torque to the rear wheel causing the rider to lose acceleration off a corner.

On the other hand, having no power pulse lets the tyre “rest,” allowing it time to grip. Another advantage of this is better tyre life.

Moving forward to the Yamaha R1’s, its inline-four crossplane engine fires at 270°-180°-90°-180°. The firing order has also been changed to 1-3-2-4, instead of the flat-plane’s 1-3-4-2.

We have 4 pistons that are all in a different position from each other. Two pistons are at the beginning of moving downwards, and two pistons are at the beginning of moving upwards.

Piston 1 is at TDC and moves to 90°, while piston 4 is at BDC and moves to 270°. Both these pistons generate a force that is directed upwards (conrod outward movement), but piston 2 is at 270° and moves to TDC, while piston 3 is at 90° and moves to BDC. Both these pistons generate a force that is directed downwards (conrod inward movement).

This means that pistons 1 and 4 are a pair that have a force upwards and pistons 2 and 3 have a force directed downwards. As such, the upward forces are cancelled out by the downward forces. Ultimately, the crossplane crankshaft has no secondary force.

Benefits of the inline-four crossplane engine

With the crossplane crankshaft design, the inertia force (= inertia torque) is reduced to almost zero, apart from a little due to flex and torsion from the crankshaft. So what remains is the ‘pure’ combustion torque. The feeling of the combustion torque is what is meant by throttle feeling. The combustion torque is no longer overruled by the inertia torque with the crossplane crankshaft. This gives the rider the feeling he is directly controlling the rear wheel without any interference, thus improving the ride ability.

In addition to this is the irregular firing order which allows the rear tyre to rest as we mentioned earlier.

This was why Valentino Rossi chose the crossplane engined YZR-M1 when he joined the Yamaha MotoGP team in 2004. To him, it had a smoother throttle response and promoted better rear tyre traction. Remember this was when traction control and certainly aerodynamics were still decades away.

Yamaha then became the first manufacturer to adopt that crankshaft arrangement to a road bike, namely the YZF-R1 in 2009. It continues to be the only inline-four road bike with a crossplane crankshaft.

So, what about CP2 and CP3?

There are two types of parallel-twin crankshaft layouts, initially. Traditionally, the British twins used a 360° layout which the both pistons rose and fall together. Then, it was revised to the 180° twin, which one piston is at TDC while another is at BDC. But the former has a high secondary and primary vibrations, while the latter has high primary vibrations.

So, Yamaha first introduced the TRX850 in 1995 with a parallel-twin engine with a 270° crankshaft, to mimic the firing order of a 90° V-Twin’s.

But somehow, the TRX850 faded away. Not the engine layout, though, because Yamaha revived that format in the MT-07 in 2014, and called it the CP2 (crossplane 2-cylinder).

As for the CP3, as you may have guessed it, it is a three-cylinder engine with a crossplane crankshaft. However, it has to be said that the inline three-cylinder engine is already a crossplane engine, as the crankpins are spaced at 120° to each other rather than being on a flat-plane. It is just a matter of familial continue (and for marketing purposes) that Yamaha calls it the CP3.

So while the CP2 and CP3 are trademarks for Yamaha, the technology is not.

The 2025 Honda CB1000 Hornet has been launched after the prototype was first revealed at EICMA 2023.

There are two versions, namely a standard and an up-spec’ed SP.

Engine

Both versions are powered by a 1000cc, inline-four, DOHC, 16-valve engine. The standard’s engine does 150hp at 11,000 RPM and 104Nm at 9,000 RPM. On the other hand, the SP versions engine produces 155hp at 11,000 RPM and 107Nm at 9,000 RPM courtesy of an exhaust system which features a servo-operated valve which opens at 5,700 RPM.

The CB1000R’s engine was derived from an old CBR1000RR Fireblade which produced 189hp at 13,000 RPM and 116Nm at 11,000 RPM. So, the CB’s engine has a lower RPM ceiling and produces its peak power and torque at lower RPMs.

The engine’s power is channelled through an assist and slipper clutch, and six-speed transmission which were also derived from the previous generation CBR1000RR. The CB1000 SP has a quickshifter as standard equipment which is an option for the standard version.

Chassis

The 2025 Honda CB1000 Hornet uses a twin-spar steel frame which is claimed to be 70% more torsionally rigid than the previous CB1000R. While the 1455mm wheelbase and 25° rake are identical to the CB1000R’s, weight is now biased towards the front, 51.2%/48.8% (50.9%/49.1% on the SP), by shifting the engine forward along with components like the rear shock and battery. The airbox is located above the engine’s cylinder head.

Both versions share the same 41mm Showa SFF-BP upside-down forks that are adjustable for compression, rebound and preload. At the back, the standard version gets a Showa monoshock with preload and rebound adjustments. The SP version gets an Öhlins TTX36 shock adjustable for preload, rebound and compression. Both modes use the same conventional aluminium swingarm compared to the single-sided and more expensive CB1000R.

While both variants use radial-mounted, four-pot front calipers on 310mm discs, the standard Hornet’s calipers are from Nissin while the SP uses Brembo Stylema. The rear Nissin single-pot caliper and 240mm disc are shared by both versions, and while there’s 2-channel ABS.

Electronics

There is a 5-inch colour TFT display with phone connectivity. Accompanied by Honda’s RoadSync app and a smartphone gives all the usual connectivity, including turn-by-turn navigation. A bar-mounted, backlit, four-way toggle switch controls the screen, and when paired to a Bluetooth headset you also get control over calls and music.

Both variants have five riding modes namely Rain, Standard, Sport, and two user presets. There are also four levels of traction control, engine braking control, and wheelie control. There is no IMU for cornering ABS and traction control, however.

Other specs include all-LED lighting with dual projector-style headlamps and an Emergency Stop Signal (ESS) function that flashes the hazard lights automatically during hard braking.

Price

The standard 2025 Honda CB1000 Hornet is priced at £8,995 (RM50,487.64), while the SP version is £9,995 (RM56,109.24). These prices are the same as the Yamaha MT-09’s in the UK.

Will it make it here? Who knows.

It is now in the middle of the transitional season in Malaysia, bringing sudden thunderstorms and heavy downpours. And as expected, there will be flash floods, like this morning on 15 October 2024.

While it is safest to sit out from riding in pouring rain and flooded roads, there is no escaping it at times, especially around flood-prone areas where the roads remain flooded even after rain has stopped.

Here are our tips for riding through flash floods (and deep puddles of water).

1. Stop and inspect

Treat riding through deep water like like it is adventure riding. No sane adventure rider will just blast headlong into an unknown body of water without first inspecting its depth, potential hazards underwater and exit on the other side.

While you may not have to get off your bike and walk through floods on the road you travel on each day, you do need to stop and look for clues. If there is another vehicle pushing through the water, note how deep it is. Observe if there is a strong water current from one side of the road to the other.

If the water is too deep or current’s too strong, forget it. Just wait for it to subside.

If you do not already know the location of your engine’s air intake, now is the good time to start. Check if it is high enough above the water. (This also applies to car drivers.)

2. Stand Up

Standing up on the footpegs promotes better stability at slow speeds, allowing you to control the bike. It can also keep your head hence eyes above water splashes so you can see where you are going.

3. Go Slow (and straight)

This goes without saying.

Throwing up a big splash may look spectacular in pictures but it is not a good idea in real world situations unless you are riding an enduro motorcycle. Hitting a deep body of water at speed would most turn the water into a liquid brake/barrier. The bike will cut through the first few metres easily before coming to a sudden halt and causing the rider to lose control (or even thrown off).

Keep your speed steady and as low as possibleto keep the water’s bow wake below the height of the engine’s air intake. Remember, you are riding a motorcycle, not a jetski.

It is also best to stay off the sides of the road and ride in the middle of the lane as roads in Malaysia are typically higher in the middle.

4. Keep moving

Do not pull in the clutch or shut the throttle abruptly.

Maintain a steady throttle and speed in the gear you are in right now, even if you should feel a tyre or tyres kicking loose when contacting something in the water. In fact, you should open the throttle a bit more if that happens.

Roll off the throttle smoothly if you need to slow down more and stay off the brakes.

5. Exiting

Do n0t gun it immediately after exiting the flood. You may increase your speed, but do not slam open the throttle, without first giving the time for the water or whatever debris collected on the bike to “drop off.”

Also, with the bike still moving, apply the brakes lightly to clean them.

6. Kill It!

But what if you hit, for example, a pothole and the bike goes down?

Make the effort to kill the engine before you lay the bike down into the water. You would most probably have the time to do so since you were riding at a slow speed, right? Right? Regardless, the engine should be shut down as quickly as possible.

An internal combustion engine is basically an air pump which sucks in air, adds fuel to it, compresses the mixture and sets it alight. But water is incompressible and non-combustible (duh!), and therefore has the potential of causing catastrophic engine damage.

Do not immediately attempt to start a motorcycle that has been lying underwater. Instead, you should pull out the spark plugs and the airbox cover to check for water ingress. If the spark plug electrodes are wet, do not reinstall them, but turn on the bike’s ignition and crank the starter a few times to push the water out of the combustion chamber.

Reinstall only when it is sufficiently dry.

Conclusion

Riding through a flood is n0t difficult but one should do it with care and logic, obviously. Sticking to the above steps will have you home way ahead of car drivers, instead of ending up swimming in that filthy water. Think of it as urban adventure riding.

Several areas in Kuala Lumpur were hit by flash floods following continuous heavy rain since 8.30 this morning. The rain had caused Sungai Batu, Sungai Klang and Sungai Gombak to overflow.

Kuala Lumpur City Hall’s (DBKL) Corporate Planning Department Media Unit said the affected areas are Jalan Pantai Baharu, Jalan Parlimen (Dato’ Onn Roundabout) and Jalan Kinabalu.

“Other areas affected are Jalan Maharajalela, Jalan Travers, Jalan Damansara (under the Semantan flyover), Jalan Ledang, Jalan Segambut and Jalan Genting Klang opposite Shell and opposite Tunku Abdul Rahman University (UTAR), Jalan Sultan Azlan Shah and Jalan Sultan (Petaling Street).

“The incident was caused by a very high rainfall which exceeded 60 millimeters (mm) per hour which the rain reading at the city center rain station exceeded 114 mm per hour,” he said in a statement today.

He said that DBKL officers went to the field to ensure that the situation in the area was under control.

“The work includes traffic dispersal to help smooth the movement of traffic flow.

“As of 10.45 this morning, all the main routes in the city center have been opened except Jalan Rahmat which is closed one way,” he said.

He said, DBKL also activated two static pumps in Jalan Sultan Azlan Shah.

For the record, locations around Dato’ Onn Roundabout were flooded and DBKL brought in three portable pumps to suck up stagnant water which caused the situation to return to normal around 9.18 this morning.

The cleaning work around Jalan Parlimen has been completed by DBKL, while the cleaning work in Jalan Sultan is still ongoing.

Based on the proactive actions taken by DBKL, the majority of the affected areas can be controlled and the stagnant water recedes within 30 minutes.

Following that, road users are advised to be careful through areas that have not fully receded yet.

A brake problem is believed to be the cause of a trailer ramming six vehicles at the Sri Medan traffic light intersection, in Batu Pahat, Johor yesterday.

In the incident, a trailer loaded with bricks driven by a 46-year-old man crashed into four cars and two motorcycles that were waiting for the traffic light to turn green.

Batu Pahat District Police Chief, Assistant Commissioner Shahrulanuar Mushaddat Abdullah Sani, said the accident occurred when the lorry involved was from Parit Sulong on its way to Johor Bahru.

He said, as soon as he arrived at the location with the road going down the hill, the driver noticed that the trailer had a brake problem before crashing into the vehicle stopped at the traffic light intersection.

“Preliminary investigations by the District Traffic Investigation and Enforcement Division (BSPTD) found that the accident occurred at 3.47pm.

“The crash also caused six vehicles to suffer severe damage but no casualties were reported as a result of the incident.

“The results of the initial urine screening test of the trailer driver involved were free from the influence of drugs,” he said in a statement today.

Shahrulanuar said that the police are still conducting an investigation and the case is being investigated according to Section 43 (1) of the Road Transport Act 1987 for driving recklessly and recklessly to the point of causing an accident.

Therefore, he said, people with information are asked to come to the nearest police station to help with the investigation.

Earlier, it went viral on social media of a lorry speeding and crashing into several vehicles in Sri Medan.

After crashing into several vehicles, the lorry then stopped about 100 meters from the scene of the incident.

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