Electric Motors for Boats: Understanding Technology

Understanding Electric Motors for Boats and Propellers, FAQ's

Q: Understand a propeller on an electric boat:

In essence, a boat propeller is a sophisticated device that efficiently moves water backward and creates pressure differences around its blades, resulting in the forward thrust needed to propel the vessel through the water.

Pitch: The pitch of a propeller is the theoretical distance it would move forward in one complete revolution if it were “screwing” through a solid medium (like wood). In water, there’s always some “slip” because water is a fluid, so the actual distance traveled is less than the theoretical pitch. 
Diameter: The overall width of the propeller, which affects the amount of water it can interact with.
Number of Blades: Propellers can have varying numbers of blades (2, 3, 4, or more). More blades generally provide more thrust and smoother operation but can also increase drag.
Cavitation: This is a phenomenon where rapid pressure drops around the propeller blades cause vapor bubbles to form in the water. When these bubbles collapse, they can cause noise, vibration, and even damage to the propeller blades.
Engine Torque to Thrust: The engine provides rotational power (torque) to the propeller shaft. The propeller’s design effectively converts this rotational torque into linear thrust to propel the boat.

Q: What is torque?

To understanding think of torque as the “twisting power” that the motor delivers. It’s what makes something rotate.

When you use a wrench to tighten a bolt, you’re applying torque. The harder you push on the wrench (force) and the longer the wrench is (distance from the pivot), the more twisting power (torque) you generate to turn the bolt.
Similarly, the motor in your boat applies “twisting power” to the propeller shaft.

Torque is absolutely essential for a boat’s propeller to work because:

Pushing Through Water: Water is much denser and harder to push through than air. The propeller blades need to be turned with a lot of “twisting power” (torque) to effectively push this water backwards. This is what creates the forward thrust that moves your boat. Think about it: If your motor didn’t have enough torque, the propeller wouldn’t be able to “grab” and push the water effectively, and your boat would just sit there or move very slowly.
Getting the Propeller Spinning: When you first start your boat, the propeller is still. The motor needs enough torque to overcome the “laziness” (inertia) of the propeller and the water around it, and get it spinning up to speed.
Maintaining Speed (and Fighting Resistance): As your boat moves through the water, the propeller is constantly working against the drag and resistance of the water. The motor needs to keep delivering consistent torque to keep the propeller spinning at the right speed to maintain your boat’s speed. If you encounter strong currents, waves, or if you’re carrying a heavy load, the resistance on the propeller increases. Your motor needs to be able to deliver even more torque to overcome this extra resistance and maintain your desired speed.
Acceleration and Power: Getting Up to Speed: If you want your boat to accelerate quickly, the motor needs to rapidly increase the torque it delivers to spin the propeller faster. Carrying Weight: If you have a lot of people or gear on your boat, it’s heavier. The motor needs more torque to spin the propeller hard enough to push that extra weight through the water.

In simple terms: Torque is the muscle that your boat’s motor uses to twist the propeller through the water, allowing your boat to move, accelerate, and carry loads. Without enough torque, your boat would be dead in the water!

Q: On motor specifications what is the difference between “rated” and “peak” torque?

“Rated torque” and “instant torque” both describe the torque capabilities of a motor, but they differ in terms of the duration for which that torque can be sustained and their typical applications:

Rated Torque (Tr ): This is the torque a motor can continuously produce without overheating or sustaining damage over an extended period. It represents the motor’s sustainable output under normal operating conditions. The powerful Törkmar motor is rated at 143.0 Nm for an S2-60min duty cycle. Which in engineering terms is continuous.

Instant Torque (Ti ): This refers to the absolute maximum torque the motor can deliver for an extremely brief period. It’s essentially the motor’s capability at zero speed, or the maximum torque available momentarily, often limited by the instantaneous current the motor can handle. The Törkmar motor has an instant torque rating of 245.0 Nm with an instant current of 660.0 Arms.

Q: Why is converting my diesel narrowboat to electric a good idea?

Converting your diesel narrowboat to electric propulsion offers a wealth of advantages, transforming your boating experience to be more enjoyable, sustainable, and cost-effective in the long run.

Environmental Benefits: Electric motors produce zero direct emissions at the point of use, significantly reducing your carbon footprint. This means no more harmful exhaust fumes polluting the air or diesel spills contaminating our precious canals and rivers, aligning with growing efforts towards more sustainable boating practices. By making the switch, you actively contribute to preserving the natural beauty of the UK’s inland waterways for future generations. For more on environmental benefits, you can explore resources from organisations like The Green Blue, a leading authority on sustainable boating.

Enhanced Onboard Experience: One of the most immediate and appreciated benefits is the near-silent operation of an electric motor. Gone are the noisy vibrations and rumble of a diesel engine; instead, you’ll glide peacefully through the water, allowing you to fully appreciate the tranquility of your surroundings. Electric motors also offer instant torque and precise control, making low-speed maneuvering in locks, marinas, and tight spots far smoother and easier. This also means a cleaner boat, free from diesel smells, oil residue, and exhaust fumes.

Lower Running Costs & Maintenance: While the initial investment in an electric conversion can be significant, the long-term financial benefits are compelling. Electricity is generally more affordable than diesel, leading to substantial fuel savings over time. Furthermore, electric motors have fewer moving parts compared to complex diesel engines, resulting in dramatically reduced maintenance requirements and associated costs. This means less time in the dry dock and more time enjoying the water.

Future-Proofing Your Vessel: As environmental regulations become increasingly stringent, transitioning to electric propulsion helps future-proof your narrowboat. You’ll be ahead of potential restrictions on combustion engines in certain areas and contributing to a greener future for recreational boating.

At Torkmar, we specialise in high-torque, efficient electric motors designed for narrowboats. Discover our range of Electric Motors for Narrowboats and comprehensive Electric Conversion Solutions to power your next adventure. If you’re considering a conversion, feel free to Contact Us for a detailed quote and to discuss how our Torkmar Electrical Cupboard Solution can simplify the process. For more general information on electric boating, the Inland Waterways Association (IWA) offers valuable insights.

Q: What needs to be done to convert a diesel narrowboat to electric using a Torkmar direct drive motor?

Converting your narrowboat to a quiet, efficient electric system with a Torkmar direct drive motor involves a structured process, ensuring seamless integration and optimal performance.

1. System Design & Planning: First, we’ll help assess your boat and energy needs. This determines the perfect Torkmar direct drive PMAC motor size (typically 15kW) and the optimal battery bank capacity for your cruising range and onboard power. Proper planning ensures the high-torque efficiency of your Torkmar motor is maximised.

2. Diesel System Removal: Your old diesel engine, gearbox, and exhaust are carefully removed. This creates a clean, quiet engine bay, ready for your new electric propulsion.

3. Torkmar Direct Drive Motor Installation: Your Torkmar direct drive PMAC motor is installed, often directly connecting to your existing propeller shaft. Our motors are designed for high torque to effortlessly turn large narrowboat propellers, ensuring excellent propulsion and smooth handling.

See a conversion in action: Watch a diesel narrowboat electric conversion on YouTube.

4. Battery Bank Integration: A robust lithium-ion battery bank is installed to store energy for propulsion and onboard power. These require secure, ventilated compartments and integrate with a Battery Management System (BMS) for safety and longevity.

5. Smart Charging Infrastructure: To keep you powered, we integrate:

Shore Power: For charging when moored.
Inverter/Charger: Converts power for battery charging and onboard AC appliances.
Solar Panels (Recommended): Roof-mounted solar significantly extends your range, providing continuous, free energy.
Generator (for Hybrids): For serial hybrid setups, a quiet generator can be added for extended range charging.

6. Simplified Electrical Systems: Our Torkmar Electrical Cupboard Solution streamlines installation, housing key components in a neat, pre-assembled unit. This simplifies wiring and ensures your boat’s entire electrical system works harmoniously with your new electric drive.

7. Intuitive Controls & Monitoring: New helm controls provide smooth throttle response. A clear display monitors battery levels, power consumption, and range, giving you complete confidence.

Choosing a Torkmar direct drive motor means investing in a quieter, cleaner, and more efficient narrowboat journey. Explore our Electric Motors for Narrowboats and Electric Conversion Solutions, or Contact Us to discuss your project.

Q: On an electric motor for a boat, what is the advantage of Törkmar’s internal bearing compared to using an external thrust bearing?

Unlike systems that rely on an external thrust bearing or block – which requires extra space and adds components to fit – Törkmar motors utilise a high-capacity double row angular contact bearing sealed within the motor housing. This bearing’s design effectively handles the axial thrust from the propeller, as well as radial loads. Its sealed nature protects against contaminants, contributing to a longer, more reliable life with less maintenance. By integrating this function, Törkmar makes the fitting process simpler and the overall propulsion system more compact, making life easier for boat builders.

Q: What is the best propeller for the electric motor my boat?

A boat propeller moves water forward by applying fundamental principles of physics, primarily Newton’s Third Law of Motion and Bernoulli’s Principle. Here’s a breakdown:

1. Newton’s Third Law of Motion

The most intuitive way to understand a propeller is through Newton’s Third Law, which states that for every action, there is an equal and opposite reaction. A propeller’s blades are twisted and angled (this angle is called pitch) like a screw thread. As the engine rotates the propeller, these angled blades push a mass of water backward. 

The action of the propeller pushing water backward creates an equal and opposite reaction force, which is the thrust that pushes the boat forward. The more water the propeller pushes backward, and the faster it accelerates that water, the greater the forward thrust on the boat.

2. Bernoulli’s Principle: Pressure Differential

Just as an aircraft wing generates lift by creating a pressure difference between its upper and lower surfaces, a propeller blade works similarly in water. Each propeller blade has a distinctive curved or airfoil-like shape. As the blade rotates through the water the curved front (or “suction”) side of the blade creates a longer path for the water to travel over, causing the water to speed up. According to Bernoulli’s principle, an increase in fluid velocity results in a decrease in pressure. This creates a low-pressure area in front of the blade. On an aeroplanes wing this creates lift. On a boat this creates a forward motion.

Q: If I have an electric propulsion motor on my boat will I get a reduction in my on water fees in the UK?

Yes, if you have an electric propulsion motor on your boat in the UK, you may be eligible for a reduction in your on-water fees, specifically your boat licence fees.

Environment Agency (EA) and Canal & River Trust (CRT): Both the Environment Agency and the Canal & River Trust (who manage most of the inland waterways in the UK) offer discounts for electrically powered boats. This can be as much as a 25% discount on the annual licence fee.
Broads Authority: The Broads Authority also encourages environmentally-friendly propulsion and offers reduced charges for electrically powered motor craft.
“Sole Means of Propulsion”: It’s often the case that the discount applies if the electric motor is the sole means of propulsion for your boat. However, some “series hybrid” setups (where a diesel generator charges batteries that then power an electric motor) have also qualified for the discount, as the electric motor is still the direct means of propulsion.

These discounts are part of a broader push in the UK to encourage more sustainable and low-carbon boating.

Q: What is the best electric motor for a narrowboat?

When considering an electric motor for a narrowboat, Törkmar specializes in high-torque Permanent Magnet AC (PMAC) electric motors designed specifically for inland waterways.

According to Törkmar, key characteristics of a suitable electric motor for a narrowboat include:

High Torque: Their motors deliver impressive torque, which is crucial for maneuvering narrowboats efficiently, especially with larger propellers. They emphasize that the propeller, not just the motor, is key to movement, and a high-torque motor can easily turn a large propeller for better efficiency.
Efficiency: Törkmar’s motors are engineered for superior energy efficiency, aiming for minimal energy consumption to ensure optimal performance and extended time on the water.
Quiet Operation: They are designed to be extremely quiet, allowing for a more peaceful boating experience where you can hear the sounds of nature rather than the engine.
Suitability for Displacement Boats: The motors are specifically designed for displacement hulls, which are typical of narrowboats, providing excellent propulsion and maneuverability.
Ease of Installation (with solutions): Törkmar offers solutions like their “Electrical Cupboard Solution” to simplify the installation process and reduce costs for electric power systems on narrowboats.

In essence, while Törkmar does not explicitly name “the best” motor in a universal sense, their focus is on providing robust, efficient, quiet, high-torque PMAC motors that are well-suited for the unique demands of narrowboats on inland waterways, emphasizing the importance of matching the motor to a large propeller for optimal performance.

You can find more information Plugboats: Törkmar High Torque Marine Motors for Inland Waterways – Plugboats.

Q: How does an 8-pole, 3-phase Permanent Magnet Alternating Current (PMAC) electric motor work on my boat?

Cleverly by harnesing the interaction between a magnetic field created by permanent magnets and a rotating magnetic field generated by alternating current.

An 8-pole, 3-phase Permanent Magnet Alternating Current (PMAC) motor utilizes the interaction between a magnetic field created by permanent magnets and a rotating magnetic field generated by alternating current.

The motor consists of two main parts:

The Rotor: This is the rotating part of the motor. In an 8-pole PMAC motor, the rotor contains the permanent magnets. As you mentioned, these magnets are arranged with alternating North (N) and South (S) poles, specifically 4 North and 4 South poles in this case.
The Stator: This is the stationary part that surrounds the rotor. The stator houses coils of copper wire, typically wound in a specific pattern.

The motor is powered by a 3-phase alternating current (AC) supply. AC electricity, unlike direct current (DC), periodically reverses direction and changes in magnitude, following a sinusoidal pattern (like a sine wave). In a 3-phase system, there are three separate AC waveforms, each phase being out of sync with the others by 120 electrical degrees.

When the 3-phase AC current flows through the coils in the stator, it creates a magnetic field. Because the current in each phase is constantly changing and the phases are offset by 120 degrees, the magnetic field produced by the stator coils isn’t static; it rotates. The speed of this rotating magnetic field is directly related to the frequency of the AC power supply and the number of poles in the motor.

The permanent magnets on the rotor have their own fixed magnetic field. The fundamental principle of motor operation is the interaction between magnetic fields: opposite poles attract, and like poles repel. As the stator’s magnetic field rotates, it exerts forces on the permanent magnets of the rotor. The North poles of the stator’s rotating field attract the South poles of the rotor magnets, and repel the North poles. Simultaneously, the South poles of the stator’s field attract the North poles of the rotor magnets and repel the South poles.

This continuous process of attraction and repulsion between the rotating magnetic field of the stator and the fixed magnetic field of the rotor’s permanent magnets creates a torque (a rotational force) on the rotor, causing it to spin. The rotor is attached to a shaft, and this shaft can be connected to a load, such as a propeller on a boat. As the motor spins the shaft, it turns the propeller, providing the thrust needed to move the boat through the water.

In summary, an 8-pole, 3-phase PMAC motor works by using a rotating magnetic field generated by 3-phase AC in the stator to exert forces on the permanent magnets of the rotor, resulting in continuous rotation and the ability to perform mechanical work.