Latest news with #LynfelOwen
Motor 1
a day ago
- Automotive
- Motor 1
'Dirtiest Part of the Car': Why the Range Rover Electric Skips the Front Trunk
It's been more than two years since Land Rover announced plans to launch a fully electric Range Rover. While we're still waiting for the official debut, the teaser campaign has already revealed much of the luxury SUV's design. Visually, it will look nearly identical to its combustion-engine counterpart, with which it shares the same platform. Unlike some EVs that offer a front trunk in place of an engine, the Range Rover Electric won't feature one. In an interview with Australian magazine CarExpert , the vehicle's chief engineer explained why the first Range Rover without a combustion engine won't have a supplementary front cargo area. Land Rover surveyed customers on the matter, and the consensus was that the rear luggage space was sufficient. Lynfel Owen confirmed that the rear cargo volume will match that of the combustion-engine model, with no need to raise the floor to accommodate the 117-kWh battery pack. Photo by: Land Rover However, packaging the 344 prismatic cells in a double-stacked layout while maintaining cargo space means the electric Range Rover will be offered exclusively with two rows of seats. A seven-seat version isn't planned due to packaging constraints. Land Rover will sell a spare wheel, but it'll eat into the luggage capacity by sitting above the cargo floor. Customer preferences weren't the only reason Land Rover skipped the front trunk. Owen rhetorically asked: 'Why would I want to lean against the dirtiest part of the car to put stuff?' Jaguar Land Rover took a different approach with the I-Pace , which offered a small 27-liter (0.95 cubic feet) front storage compartment. That model was discontinued at the end of last year, and going forward, all new Jaguars will be electric-only. Although Owen wasn't involved in the I-Pace's development, he acknowledges that missteps were made: 'We've learned that we can't do that to our customers, and we're not going to do that again.' Designed by Ian Callum and built in Graz, Austria by Magna Steyr, the I-Pace struggled with reliability and frequently ranked near the bottom of customer satisfaction surveys. Photo by: Land Rover While the interview didn't delve into curb weight, Autocar reports that JLR is targeting 2,800 kilograms (6,172 pounds). That's hardly lightweight, but it would make the Range Rover Electric 285 kg (629 lbs) lighter than the Mercedes G580 with EQ Technology. Like the Range Rover, the electric G-Class doesn't have a front trunk either, but compensates with a tailgate-mounted cargo box styled like a spare wheel for storing charging cables. Owen insists the electric Range Rover won't compete directly with the G580 , claiming it offers superior go-anywhere capabilities and a nicer cabin: 'This is still a Range Rover. It is not an EV. There really isn't another EV out there doing what this car does. Not at this level of off-road ability with this type of luxury.' The world premiere is scheduled for later this year, with deliveries expected to kick off in 2026. Catch Up With The Range Rover Electric: The Electric Range Rover Looks Identical to the Gas Model Range Rover's First Electric SUV Promises V8 Performance Sources: CarExpert , Autocar Share this Story Facebook X LinkedIn Flipboard Reddit WhatsApp E-Mail Got a tip for us? Email: tips@ Join the conversation ( )
The Advertiser
a day ago
- Automotive
- The Advertiser
Inside the Range Rover Electric: An interview with the chief engineer
The Range Rover Electric marks a turning point for Land Rover's flagship model: its first foray into fully electric propulsion. While it retains the traditional Range Rover silhouette and off-road DNA, this new model integrates electric vehicle (EV) hardware developed in-house, dual electric motors, and an 118kWh battery pack. At the centre of this transformation is Lynfel Owen, the chief engineer of vehicle engineering for the Range Rover, Range Rover Sport and Defender model lines. With more than 25 years in the automotive industry – including senior roles in Ford and now JLR – Mr Owen is responsible for engineering sign-off and attribute delivery across all three nameplates. A Nottingham University MEng graduate, Mr Owen has spent the last decade overseeing the transition to EV propulsion within JLR's most iconic products. Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. "I pretty much only ever worked on Range Rover," Mr Owen said. "I've done a few other projects. I didn't work on the [Jaguar] I-Pace. I was working on the previous-generation Range Rover." Still, he was direct about the lessons learned from the Jaguar I-Pace, which was plagued with reliability issues for its electric drivetrain and battery pack. "We've learned that we can't do that to our customers, and we're not going to do that again." The battery pack in the Range Rover Electric is made up of NMC (nickel manganese cobalt) chemistry prismatic cells stacked in two layers. "We've got two layers, 172 on each layer (344 in total)," Mr Owen explained. "118 usable kilowatt hours out of this battery." The pack is assembled in-house, though the cell supplier remains unnamed: "We're working with a partner on cells. Not at liberty to tell who they are. Well recognised within the industry." We very much suspect it's BYD. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and comes down the same production line. The battery pack supplies energy to a twin-motor setup producing 404kW of power and 850Nm of torque. The pair of permanent magnet drive units, one on each axle, makes use of ultra-thin discs in the rotor assembly, which are precisely machined to less than 0.2mm, allowing more discs per motor and subsequently more torque. The company claims the enhanced design and silicon carbide semiconductor technology give the Range Rover electric motors 70 per cent more torque and reduced energy-sapping losses by 40 per cent compared to the previous-generation unit found in the Jaguar I-Pace. To test all of this, JLR engineers have been the world over. "We're making sure we learn from, you know, our mistakes with respect to I-Pace. So we're testing all aspects of the car… we've just had a northern hemisphere winter that we've completed, so we've been doing our low-mu testing on the frozen lakes," explained Mr Owen. Charging specs are modern and flexible. "22 kilowatt," Mr Owen confirmed for AC charging. "10 to 80 per cent in about 20 minutes" for DC at 350kW. The car can also charge via AC on either side: "We've got AC port on both sides. Again, we listen to our customers." That practicality carries through the rest of the vehicle. "Some people have got [chargers] bolted on. Their garage might have two or three cars… [so you don't have to use a] 15 metre cable." Mr Owen described the thermal management system – ThermAssist – as a briefcase-sized unit sitting above the electric drive unit. "Cabin comfort. Battery temperature. Whether it's to cool it down, whether it's to warm it up. Recovering heat from the air at minus 15… It also reduces the heating energy consumption by over 40 per cent [compared to I-Pace]." On why the Range Rover Electric doesn't have a front trunk: "We spoke to our customers… none of them have an issue [with] lack of storage space… The rear cargo space is exactly the same. We haven't had to raise the floor. The only compromise we have to make is we're not able to offer a seven-seat derivative." He added bluntly: "Why would I want to lean against the dirtiest part of the car to put stuff?" From a suspension perspective, a switchable twin-chamber air suspension is utilised while regenerative braking delivers one-pedal driving. Despite its large battery, weight has been closely managed. "Weight is the biggest enemy to any EV, because you've got to cart it around. And when it's empty, it's dead weight." Official range figures are still being finalised, and Mr Owen wouldn't be drawn into the Range Rover electric's weight, but we suspect it will be around 2500kg kerb. As for the driving range: "It's going to be… It's in excess of 300 miles (480km). We use EPA, because we find EPA is pretty much spot on." Brands like Ferrari and Rolls-Royce have committed to providing battery repair and updates to their electrified vehicles indefinitely, given the price point and customer base of their cars. JLR is in a similar spot whereby the cars are not disposed of like cheaper EVs might be. Questioned on how the company plans to keep its EVs driving on the road in the decades to come, Mr Owen said battery longevity and servicing are also under review. "Reworking cells, individual cells, sounds great. But the amount of time and effort and safety protocols that go into that – we don't want to take a customer out of their car over and over again." Still, Mr Owen confirmed long-term support is legislated: "There's actually legislation (in the works) that dictates how long you've got to do it. And it's a really long time in the UK… and it's coming in around the world." Ultimately, though, the Range Rover Electric is a Range Rover first and electric second. "This is still a Range Rover. It is not an EV," Mr Owen said. "Our customers buy a Range Rover. Then they decide which propulsion system they want." That applies to future performance versions as well. "As part of the Reimagine strategy, we've committed to electrifying all the vehicles in our range by 2030." This might mean that at some point in the not-so-distant future, even the Range Rover Sport SV might go electric, but that remains to be seen. The brand makes use of a five-channel active road noise cancellation system specifically for the electric Range Rover, which is now the quietest Range Rover ever. It uses four accelerometers outside the vehicle to detect noise, which the system then automatically cancels using sound frequencies delivered through the audio system. The cabin is now so quiet that Range Rover has also created a unique sound for its electric mode, which responds to driver inputs. While it would be difficult to tell the electric Range Rover apart from a fuel-guzzler from the outside, little details like the wheels, which are aerodynamically optimised, are evident. Even the front grille has been reduced in weight. The motors are also a JLR development. "The actual motors, the electric motors inside, and the inverters are common front to rear… obviously, the packaging differs… completely different castings, but the same power." Asked whether they benchmark other EVs, Mr Owen said: "We benchmark all the time – not just for electric Range Rover, but for everything." But he doesn't see a direct rival: "There really isn't another EV out there doing what this car does. Not at this level of off-road ability with this type of luxury." As for when customers can expect to take delivery? "We'll launch it when we're ready, and it's good." That should see the Range Rover electric start production some time in 2026. MORE: Explore the Range Rover showroom Content originally sourced from: The Range Rover Electric marks a turning point for Land Rover's flagship model: its first foray into fully electric propulsion. While it retains the traditional Range Rover silhouette and off-road DNA, this new model integrates electric vehicle (EV) hardware developed in-house, dual electric motors, and an 118kWh battery pack. At the centre of this transformation is Lynfel Owen, the chief engineer of vehicle engineering for the Range Rover, Range Rover Sport and Defender model lines. With more than 25 years in the automotive industry – including senior roles in Ford and now JLR – Mr Owen is responsible for engineering sign-off and attribute delivery across all three nameplates. A Nottingham University MEng graduate, Mr Owen has spent the last decade overseeing the transition to EV propulsion within JLR's most iconic products. Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. "I pretty much only ever worked on Range Rover," Mr Owen said. "I've done a few other projects. I didn't work on the [Jaguar] I-Pace. I was working on the previous-generation Range Rover." Still, he was direct about the lessons learned from the Jaguar I-Pace, which was plagued with reliability issues for its electric drivetrain and battery pack. "We've learned that we can't do that to our customers, and we're not going to do that again." The battery pack in the Range Rover Electric is made up of NMC (nickel manganese cobalt) chemistry prismatic cells stacked in two layers. "We've got two layers, 172 on each layer (344 in total)," Mr Owen explained. "118 usable kilowatt hours out of this battery." The pack is assembled in-house, though the cell supplier remains unnamed: "We're working with a partner on cells. Not at liberty to tell who they are. Well recognised within the industry." We very much suspect it's BYD. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and comes down the same production line. The battery pack supplies energy to a twin-motor setup producing 404kW of power and 850Nm of torque. The pair of permanent magnet drive units, one on each axle, makes use of ultra-thin discs in the rotor assembly, which are precisely machined to less than 0.2mm, allowing more discs per motor and subsequently more torque. The company claims the enhanced design and silicon carbide semiconductor technology give the Range Rover electric motors 70 per cent more torque and reduced energy-sapping losses by 40 per cent compared to the previous-generation unit found in the Jaguar I-Pace. To test all of this, JLR engineers have been the world over. "We're making sure we learn from, you know, our mistakes with respect to I-Pace. So we're testing all aspects of the car… we've just had a northern hemisphere winter that we've completed, so we've been doing our low-mu testing on the frozen lakes," explained Mr Owen. Charging specs are modern and flexible. "22 kilowatt," Mr Owen confirmed for AC charging. "10 to 80 per cent in about 20 minutes" for DC at 350kW. The car can also charge via AC on either side: "We've got AC port on both sides. Again, we listen to our customers." That practicality carries through the rest of the vehicle. "Some people have got [chargers] bolted on. Their garage might have two or three cars… [so you don't have to use a] 15 metre cable." Mr Owen described the thermal management system – ThermAssist – as a briefcase-sized unit sitting above the electric drive unit. "Cabin comfort. Battery temperature. Whether it's to cool it down, whether it's to warm it up. Recovering heat from the air at minus 15… It also reduces the heating energy consumption by over 40 per cent [compared to I-Pace]." On why the Range Rover Electric doesn't have a front trunk: "We spoke to our customers… none of them have an issue [with] lack of storage space… The rear cargo space is exactly the same. We haven't had to raise the floor. The only compromise we have to make is we're not able to offer a seven-seat derivative." He added bluntly: "Why would I want to lean against the dirtiest part of the car to put stuff?" From a suspension perspective, a switchable twin-chamber air suspension is utilised while regenerative braking delivers one-pedal driving. Despite its large battery, weight has been closely managed. "Weight is the biggest enemy to any EV, because you've got to cart it around. And when it's empty, it's dead weight." Official range figures are still being finalised, and Mr Owen wouldn't be drawn into the Range Rover electric's weight, but we suspect it will be around 2500kg kerb. As for the driving range: "It's going to be… It's in excess of 300 miles (480km). We use EPA, because we find EPA is pretty much spot on." Brands like Ferrari and Rolls-Royce have committed to providing battery repair and updates to their electrified vehicles indefinitely, given the price point and customer base of their cars. JLR is in a similar spot whereby the cars are not disposed of like cheaper EVs might be. Questioned on how the company plans to keep its EVs driving on the road in the decades to come, Mr Owen said battery longevity and servicing are also under review. "Reworking cells, individual cells, sounds great. But the amount of time and effort and safety protocols that go into that – we don't want to take a customer out of their car over and over again." Still, Mr Owen confirmed long-term support is legislated: "There's actually legislation (in the works) that dictates how long you've got to do it. And it's a really long time in the UK… and it's coming in around the world." Ultimately, though, the Range Rover Electric is a Range Rover first and electric second. "This is still a Range Rover. It is not an EV," Mr Owen said. "Our customers buy a Range Rover. Then they decide which propulsion system they want." That applies to future performance versions as well. "As part of the Reimagine strategy, we've committed to electrifying all the vehicles in our range by 2030." This might mean that at some point in the not-so-distant future, even the Range Rover Sport SV might go electric, but that remains to be seen. The brand makes use of a five-channel active road noise cancellation system specifically for the electric Range Rover, which is now the quietest Range Rover ever. It uses four accelerometers outside the vehicle to detect noise, which the system then automatically cancels using sound frequencies delivered through the audio system. The cabin is now so quiet that Range Rover has also created a unique sound for its electric mode, which responds to driver inputs. While it would be difficult to tell the electric Range Rover apart from a fuel-guzzler from the outside, little details like the wheels, which are aerodynamically optimised, are evident. Even the front grille has been reduced in weight. The motors are also a JLR development. "The actual motors, the electric motors inside, and the inverters are common front to rear… obviously, the packaging differs… completely different castings, but the same power." Asked whether they benchmark other EVs, Mr Owen said: "We benchmark all the time – not just for electric Range Rover, but for everything." But he doesn't see a direct rival: "There really isn't another EV out there doing what this car does. Not at this level of off-road ability with this type of luxury." As for when customers can expect to take delivery? "We'll launch it when we're ready, and it's good." That should see the Range Rover electric start production some time in 2026. MORE: Explore the Range Rover showroom Content originally sourced from: The Range Rover Electric marks a turning point for Land Rover's flagship model: its first foray into fully electric propulsion. While it retains the traditional Range Rover silhouette and off-road DNA, this new model integrates electric vehicle (EV) hardware developed in-house, dual electric motors, and an 118kWh battery pack. At the centre of this transformation is Lynfel Owen, the chief engineer of vehicle engineering for the Range Rover, Range Rover Sport and Defender model lines. With more than 25 years in the automotive industry – including senior roles in Ford and now JLR – Mr Owen is responsible for engineering sign-off and attribute delivery across all three nameplates. A Nottingham University MEng graduate, Mr Owen has spent the last decade overseeing the transition to EV propulsion within JLR's most iconic products. Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. "I pretty much only ever worked on Range Rover," Mr Owen said. "I've done a few other projects. I didn't work on the [Jaguar] I-Pace. I was working on the previous-generation Range Rover." Still, he was direct about the lessons learned from the Jaguar I-Pace, which was plagued with reliability issues for its electric drivetrain and battery pack. "We've learned that we can't do that to our customers, and we're not going to do that again." The battery pack in the Range Rover Electric is made up of NMC (nickel manganese cobalt) chemistry prismatic cells stacked in two layers. "We've got two layers, 172 on each layer (344 in total)," Mr Owen explained. "118 usable kilowatt hours out of this battery." The pack is assembled in-house, though the cell supplier remains unnamed: "We're working with a partner on cells. Not at liberty to tell who they are. Well recognised within the industry." We very much suspect it's BYD. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and comes down the same production line. The battery pack supplies energy to a twin-motor setup producing 404kW of power and 850Nm of torque. The pair of permanent magnet drive units, one on each axle, makes use of ultra-thin discs in the rotor assembly, which are precisely machined to less than 0.2mm, allowing more discs per motor and subsequently more torque. The company claims the enhanced design and silicon carbide semiconductor technology give the Range Rover electric motors 70 per cent more torque and reduced energy-sapping losses by 40 per cent compared to the previous-generation unit found in the Jaguar I-Pace. To test all of this, JLR engineers have been the world over. "We're making sure we learn from, you know, our mistakes with respect to I-Pace. So we're testing all aspects of the car… we've just had a northern hemisphere winter that we've completed, so we've been doing our low-mu testing on the frozen lakes," explained Mr Owen. Charging specs are modern and flexible. "22 kilowatt," Mr Owen confirmed for AC charging. "10 to 80 per cent in about 20 minutes" for DC at 350kW. The car can also charge via AC on either side: "We've got AC port on both sides. Again, we listen to our customers." That practicality carries through the rest of the vehicle. "Some people have got [chargers] bolted on. Their garage might have two or three cars… [so you don't have to use a] 15 metre cable." Mr Owen described the thermal management system – ThermAssist – as a briefcase-sized unit sitting above the electric drive unit. "Cabin comfort. Battery temperature. Whether it's to cool it down, whether it's to warm it up. Recovering heat from the air at minus 15… It also reduces the heating energy consumption by over 40 per cent [compared to I-Pace]." On why the Range Rover Electric doesn't have a front trunk: "We spoke to our customers… none of them have an issue [with] lack of storage space… The rear cargo space is exactly the same. We haven't had to raise the floor. The only compromise we have to make is we're not able to offer a seven-seat derivative." He added bluntly: "Why would I want to lean against the dirtiest part of the car to put stuff?" From a suspension perspective, a switchable twin-chamber air suspension is utilised while regenerative braking delivers one-pedal driving. Despite its large battery, weight has been closely managed. "Weight is the biggest enemy to any EV, because you've got to cart it around. And when it's empty, it's dead weight." Official range figures are still being finalised, and Mr Owen wouldn't be drawn into the Range Rover electric's weight, but we suspect it will be around 2500kg kerb. As for the driving range: "It's going to be… It's in excess of 300 miles (480km). We use EPA, because we find EPA is pretty much spot on." Brands like Ferrari and Rolls-Royce have committed to providing battery repair and updates to their electrified vehicles indefinitely, given the price point and customer base of their cars. JLR is in a similar spot whereby the cars are not disposed of like cheaper EVs might be. Questioned on how the company plans to keep its EVs driving on the road in the decades to come, Mr Owen said battery longevity and servicing are also under review. "Reworking cells, individual cells, sounds great. But the amount of time and effort and safety protocols that go into that – we don't want to take a customer out of their car over and over again." Still, Mr Owen confirmed long-term support is legislated: "There's actually legislation (in the works) that dictates how long you've got to do it. And it's a really long time in the UK… and it's coming in around the world." Ultimately, though, the Range Rover Electric is a Range Rover first and electric second. "This is still a Range Rover. It is not an EV," Mr Owen said. "Our customers buy a Range Rover. Then they decide which propulsion system they want." That applies to future performance versions as well. "As part of the Reimagine strategy, we've committed to electrifying all the vehicles in our range by 2030." This might mean that at some point in the not-so-distant future, even the Range Rover Sport SV might go electric, but that remains to be seen. The brand makes use of a five-channel active road noise cancellation system specifically for the electric Range Rover, which is now the quietest Range Rover ever. It uses four accelerometers outside the vehicle to detect noise, which the system then automatically cancels using sound frequencies delivered through the audio system. The cabin is now so quiet that Range Rover has also created a unique sound for its electric mode, which responds to driver inputs. While it would be difficult to tell the electric Range Rover apart from a fuel-guzzler from the outside, little details like the wheels, which are aerodynamically optimised, are evident. Even the front grille has been reduced in weight. The motors are also a JLR development. "The actual motors, the electric motors inside, and the inverters are common front to rear… obviously, the packaging differs… completely different castings, but the same power." Asked whether they benchmark other EVs, Mr Owen said: "We benchmark all the time – not just for electric Range Rover, but for everything." But he doesn't see a direct rival: "There really isn't another EV out there doing what this car does. Not at this level of off-road ability with this type of luxury." As for when customers can expect to take delivery? "We'll launch it when we're ready, and it's good." That should see the Range Rover electric start production some time in 2026. MORE: Explore the Range Rover showroom Content originally sourced from: The Range Rover Electric marks a turning point for Land Rover's flagship model: its first foray into fully electric propulsion. While it retains the traditional Range Rover silhouette and off-road DNA, this new model integrates electric vehicle (EV) hardware developed in-house, dual electric motors, and an 118kWh battery pack. At the centre of this transformation is Lynfel Owen, the chief engineer of vehicle engineering for the Range Rover, Range Rover Sport and Defender model lines. With more than 25 years in the automotive industry – including senior roles in Ford and now JLR – Mr Owen is responsible for engineering sign-off and attribute delivery across all three nameplates. A Nottingham University MEng graduate, Mr Owen has spent the last decade overseeing the transition to EV propulsion within JLR's most iconic products. Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. "I pretty much only ever worked on Range Rover," Mr Owen said. "I've done a few other projects. I didn't work on the [Jaguar] I-Pace. I was working on the previous-generation Range Rover." Still, he was direct about the lessons learned from the Jaguar I-Pace, which was plagued with reliability issues for its electric drivetrain and battery pack. "We've learned that we can't do that to our customers, and we're not going to do that again." The battery pack in the Range Rover Electric is made up of NMC (nickel manganese cobalt) chemistry prismatic cells stacked in two layers. "We've got two layers, 172 on each layer (344 in total)," Mr Owen explained. "118 usable kilowatt hours out of this battery." The pack is assembled in-house, though the cell supplier remains unnamed: "We're working with a partner on cells. Not at liberty to tell who they are. Well recognised within the industry." We very much suspect it's BYD. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and comes down the same production line. The battery pack supplies energy to a twin-motor setup producing 404kW of power and 850Nm of torque. The pair of permanent magnet drive units, one on each axle, makes use of ultra-thin discs in the rotor assembly, which are precisely machined to less than 0.2mm, allowing more discs per motor and subsequently more torque. The company claims the enhanced design and silicon carbide semiconductor technology give the Range Rover electric motors 70 per cent more torque and reduced energy-sapping losses by 40 per cent compared to the previous-generation unit found in the Jaguar I-Pace. To test all of this, JLR engineers have been the world over. "We're making sure we learn from, you know, our mistakes with respect to I-Pace. So we're testing all aspects of the car… we've just had a northern hemisphere winter that we've completed, so we've been doing our low-mu testing on the frozen lakes," explained Mr Owen. Charging specs are modern and flexible. "22 kilowatt," Mr Owen confirmed for AC charging. "10 to 80 per cent in about 20 minutes" for DC at 350kW. The car can also charge via AC on either side: "We've got AC port on both sides. Again, we listen to our customers." That practicality carries through the rest of the vehicle. "Some people have got [chargers] bolted on. Their garage might have two or three cars… [so you don't have to use a] 15 metre cable." Mr Owen described the thermal management system – ThermAssist – as a briefcase-sized unit sitting above the electric drive unit. "Cabin comfort. Battery temperature. Whether it's to cool it down, whether it's to warm it up. Recovering heat from the air at minus 15… It also reduces the heating energy consumption by over 40 per cent [compared to I-Pace]." On why the Range Rover Electric doesn't have a front trunk: "We spoke to our customers… none of them have an issue [with] lack of storage space… The rear cargo space is exactly the same. We haven't had to raise the floor. The only compromise we have to make is we're not able to offer a seven-seat derivative." He added bluntly: "Why would I want to lean against the dirtiest part of the car to put stuff?" From a suspension perspective, a switchable twin-chamber air suspension is utilised while regenerative braking delivers one-pedal driving. Despite its large battery, weight has been closely managed. "Weight is the biggest enemy to any EV, because you've got to cart it around. And when it's empty, it's dead weight." Official range figures are still being finalised, and Mr Owen wouldn't be drawn into the Range Rover electric's weight, but we suspect it will be around 2500kg kerb. As for the driving range: "It's going to be… It's in excess of 300 miles (480km). We use EPA, because we find EPA is pretty much spot on." Brands like Ferrari and Rolls-Royce have committed to providing battery repair and updates to their electrified vehicles indefinitely, given the price point and customer base of their cars. JLR is in a similar spot whereby the cars are not disposed of like cheaper EVs might be. Questioned on how the company plans to keep its EVs driving on the road in the decades to come, Mr Owen said battery longevity and servicing are also under review. "Reworking cells, individual cells, sounds great. But the amount of time and effort and safety protocols that go into that – we don't want to take a customer out of their car over and over again." Still, Mr Owen confirmed long-term support is legislated: "There's actually legislation (in the works) that dictates how long you've got to do it. And it's a really long time in the UK… and it's coming in around the world." Ultimately, though, the Range Rover Electric is a Range Rover first and electric second. "This is still a Range Rover. It is not an EV," Mr Owen said. "Our customers buy a Range Rover. Then they decide which propulsion system they want." That applies to future performance versions as well. "As part of the Reimagine strategy, we've committed to electrifying all the vehicles in our range by 2030." This might mean that at some point in the not-so-distant future, even the Range Rover Sport SV might go electric, but that remains to be seen. The brand makes use of a five-channel active road noise cancellation system specifically for the electric Range Rover, which is now the quietest Range Rover ever. It uses four accelerometers outside the vehicle to detect noise, which the system then automatically cancels using sound frequencies delivered through the audio system. The cabin is now so quiet that Range Rover has also created a unique sound for its electric mode, which responds to driver inputs. While it would be difficult to tell the electric Range Rover apart from a fuel-guzzler from the outside, little details like the wheels, which are aerodynamically optimised, are evident. Even the front grille has been reduced in weight. The motors are also a JLR development. "The actual motors, the electric motors inside, and the inverters are common front to rear… obviously, the packaging differs… completely different castings, but the same power." Asked whether they benchmark other EVs, Mr Owen said: "We benchmark all the time – not just for electric Range Rover, but for everything." But he doesn't see a direct rival: "There really isn't another EV out there doing what this car does. Not at this level of off-road ability with this type of luxury." As for when customers can expect to take delivery? "We'll launch it when we're ready, and it's good." That should see the Range Rover electric start production some time in 2026. MORE: Explore the Range Rover showroom Content originally sourced from:
The Advertiser
a day ago
- Automotive
- The Advertiser
Range Rover Electric: 'Don't change it, just make it better"
JLR is well down the path of introducing its first electric Range Rover, which is expected sometime next year, but the company's approach is as notable for how long it has taken to come to market as it is about the philosophical debate around electrification. With JLR's previous electric vehicle (EV), the Jaguar I-Pace, not having performed well in both the sales and reliability charts, the company is adamant that this time it will wait until it's ready to release the Range Rover EV. Rather than reimagining an all-new Range Rover, the company has opted to adapt its existing design and platform to accommodate an electric powertrain, a move summarised by its internal philosophy: "Don't change it, just make it better." Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and come down the same production line. It features a substantial 118kWh usable battery – comprising 344 prismatic cells using NMC (nickel manganese cobalt) chemistry – supplying energy to the dual-motor setup producing 404kW of power and 850Nm of torque. The company claims the battery and the motors are designed and manufactured in-house, although the cells themselves likely come from BYD (Land Rover wouldn't confirm its battery supplier). Despite the new drivetrain, key characteristics such as cabin layout, boot space, and off-road geometry remain unchanged. There's also no front boot, which the engineers told is deliberate as to not add elements customers don't need. "This is about integrating electric propulsion into what is an established Range Rover design," said Lynfel Owen, chief engineer of vehicle engineering. "So you know, the target was always, how do we look at today's cars, our combustion engines and everything we do today? How do we make that better with EV propulsion?" The engineering team focused on maintaining performance and ride quality. According to Mr Owen, the Range Rover Electric benefits from upgraded suspension components – including dual-valve air springs and revised bushings – specifically tuned to handle the demands of an electric setup. Torsional rigidity is also up, with this model claiming the title of the stiffest Range Rover to date. While many EVs introduce entirely new driving experiences (like Mercedes-Benz's electric G-Wagen), Land Rover is banking on familiarity. Terrain modes from combustion models have been retained, and the company has developed its own intelligent traction control system (ITM) to manage torque across all four wheels. The ITM system allows for millisecond-level torque vectoring between wheels, with cross-axle capability and the ability to emulate both two-wheel and four-wheel drive. It replaces traditional mechanical driveline components with software precision, providing finer control in both on- and off-road environments. "We've optimised all of the terrain modes for Range Rover Electric," Mr Owen explained. "It's about making it actually comfortable off-road and reducing driver demand in challenging conditions." The model also includes adaptive thermal management with a proprietary heat pump system designed to improve efficiency and comfort. Land Rover says the system can operate in temperatures as low as -15°C, recovering waste heat to reduce energy consumption by up to 40 per cent compared with the brand's previous electric vehicle, the Jaguar I-Pace. While other manufacturers often borrow EV components from shared platforms, Land Rover's vertically integrated approach reflects its aim to control the Range Rover Electric experience end to end. It may look familiar, but beneath the skin, this is the most technologically advanced model the company has built. With more than 62,000 customers already expressing interest globally, the Range Rover Electric appears to be landing well with buyers looking for electrification without dramatic change. MORE: Explore the Range Rover showroom Content originally sourced from: JLR is well down the path of introducing its first electric Range Rover, which is expected sometime next year, but the company's approach is as notable for how long it has taken to come to market as it is about the philosophical debate around electrification. With JLR's previous electric vehicle (EV), the Jaguar I-Pace, not having performed well in both the sales and reliability charts, the company is adamant that this time it will wait until it's ready to release the Range Rover EV. Rather than reimagining an all-new Range Rover, the company has opted to adapt its existing design and platform to accommodate an electric powertrain, a move summarised by its internal philosophy: "Don't change it, just make it better." Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and come down the same production line. It features a substantial 118kWh usable battery – comprising 344 prismatic cells using NMC (nickel manganese cobalt) chemistry – supplying energy to the dual-motor setup producing 404kW of power and 850Nm of torque. The company claims the battery and the motors are designed and manufactured in-house, although the cells themselves likely come from BYD (Land Rover wouldn't confirm its battery supplier). Despite the new drivetrain, key characteristics such as cabin layout, boot space, and off-road geometry remain unchanged. There's also no front boot, which the engineers told is deliberate as to not add elements customers don't need. "This is about integrating electric propulsion into what is an established Range Rover design," said Lynfel Owen, chief engineer of vehicle engineering. "So you know, the target was always, how do we look at today's cars, our combustion engines and everything we do today? How do we make that better with EV propulsion?" The engineering team focused on maintaining performance and ride quality. According to Mr Owen, the Range Rover Electric benefits from upgraded suspension components – including dual-valve air springs and revised bushings – specifically tuned to handle the demands of an electric setup. Torsional rigidity is also up, with this model claiming the title of the stiffest Range Rover to date. While many EVs introduce entirely new driving experiences (like Mercedes-Benz's electric G-Wagen), Land Rover is banking on familiarity. Terrain modes from combustion models have been retained, and the company has developed its own intelligent traction control system (ITM) to manage torque across all four wheels. The ITM system allows for millisecond-level torque vectoring between wheels, with cross-axle capability and the ability to emulate both two-wheel and four-wheel drive. It replaces traditional mechanical driveline components with software precision, providing finer control in both on- and off-road environments. "We've optimised all of the terrain modes for Range Rover Electric," Mr Owen explained. "It's about making it actually comfortable off-road and reducing driver demand in challenging conditions." The model also includes adaptive thermal management with a proprietary heat pump system designed to improve efficiency and comfort. Land Rover says the system can operate in temperatures as low as -15°C, recovering waste heat to reduce energy consumption by up to 40 per cent compared with the brand's previous electric vehicle, the Jaguar I-Pace. While other manufacturers often borrow EV components from shared platforms, Land Rover's vertically integrated approach reflects its aim to control the Range Rover Electric experience end to end. It may look familiar, but beneath the skin, this is the most technologically advanced model the company has built. With more than 62,000 customers already expressing interest globally, the Range Rover Electric appears to be landing well with buyers looking for electrification without dramatic change. MORE: Explore the Range Rover showroom Content originally sourced from: JLR is well down the path of introducing its first electric Range Rover, which is expected sometime next year, but the company's approach is as notable for how long it has taken to come to market as it is about the philosophical debate around electrification. With JLR's previous electric vehicle (EV), the Jaguar I-Pace, not having performed well in both the sales and reliability charts, the company is adamant that this time it will wait until it's ready to release the Range Rover EV. Rather than reimagining an all-new Range Rover, the company has opted to adapt its existing design and platform to accommodate an electric powertrain, a move summarised by its internal philosophy: "Don't change it, just make it better." Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and come down the same production line. It features a substantial 118kWh usable battery – comprising 344 prismatic cells using NMC (nickel manganese cobalt) chemistry – supplying energy to the dual-motor setup producing 404kW of power and 850Nm of torque. The company claims the battery and the motors are designed and manufactured in-house, although the cells themselves likely come from BYD (Land Rover wouldn't confirm its battery supplier). Despite the new drivetrain, key characteristics such as cabin layout, boot space, and off-road geometry remain unchanged. There's also no front boot, which the engineers told is deliberate as to not add elements customers don't need. "This is about integrating electric propulsion into what is an established Range Rover design," said Lynfel Owen, chief engineer of vehicle engineering. "So you know, the target was always, how do we look at today's cars, our combustion engines and everything we do today? How do we make that better with EV propulsion?" The engineering team focused on maintaining performance and ride quality. According to Mr Owen, the Range Rover Electric benefits from upgraded suspension components – including dual-valve air springs and revised bushings – specifically tuned to handle the demands of an electric setup. Torsional rigidity is also up, with this model claiming the title of the stiffest Range Rover to date. While many EVs introduce entirely new driving experiences (like Mercedes-Benz's electric G-Wagen), Land Rover is banking on familiarity. Terrain modes from combustion models have been retained, and the company has developed its own intelligent traction control system (ITM) to manage torque across all four wheels. The ITM system allows for millisecond-level torque vectoring between wheels, with cross-axle capability and the ability to emulate both two-wheel and four-wheel drive. It replaces traditional mechanical driveline components with software precision, providing finer control in both on- and off-road environments. "We've optimised all of the terrain modes for Range Rover Electric," Mr Owen explained. "It's about making it actually comfortable off-road and reducing driver demand in challenging conditions." The model also includes adaptive thermal management with a proprietary heat pump system designed to improve efficiency and comfort. Land Rover says the system can operate in temperatures as low as -15°C, recovering waste heat to reduce energy consumption by up to 40 per cent compared with the brand's previous electric vehicle, the Jaguar I-Pace. While other manufacturers often borrow EV components from shared platforms, Land Rover's vertically integrated approach reflects its aim to control the Range Rover Electric experience end to end. It may look familiar, but beneath the skin, this is the most technologically advanced model the company has built. With more than 62,000 customers already expressing interest globally, the Range Rover Electric appears to be landing well with buyers looking for electrification without dramatic change. MORE: Explore the Range Rover showroom Content originally sourced from: JLR is well down the path of introducing its first electric Range Rover, which is expected sometime next year, but the company's approach is as notable for how long it has taken to come to market as it is about the philosophical debate around electrification. With JLR's previous electric vehicle (EV), the Jaguar I-Pace, not having performed well in both the sales and reliability charts, the company is adamant that this time it will wait until it's ready to release the Range Rover EV. Rather than reimagining an all-new Range Rover, the company has opted to adapt its existing design and platform to accommodate an electric powertrain, a move summarised by its internal philosophy: "Don't change it, just make it better." Hundreds of new car deals are available through CarExpert right now. Get the experts on your side and score a great deal. Browse now. The electric variant sits on the same flexible platform as the petrol, diesel, and plug-in hybrid Range Rovers and come down the same production line. It features a substantial 118kWh usable battery – comprising 344 prismatic cells using NMC (nickel manganese cobalt) chemistry – supplying energy to the dual-motor setup producing 404kW of power and 850Nm of torque. The company claims the battery and the motors are designed and manufactured in-house, although the cells themselves likely come from BYD (Land Rover wouldn't confirm its battery supplier). Despite the new drivetrain, key characteristics such as cabin layout, boot space, and off-road geometry remain unchanged. There's also no front boot, which the engineers told is deliberate as to not add elements customers don't need. "This is about integrating electric propulsion into what is an established Range Rover design," said Lynfel Owen, chief engineer of vehicle engineering. "So you know, the target was always, how do we look at today's cars, our combustion engines and everything we do today? How do we make that better with EV propulsion?" The engineering team focused on maintaining performance and ride quality. According to Mr Owen, the Range Rover Electric benefits from upgraded suspension components – including dual-valve air springs and revised bushings – specifically tuned to handle the demands of an electric setup. Torsional rigidity is also up, with this model claiming the title of the stiffest Range Rover to date. While many EVs introduce entirely new driving experiences (like Mercedes-Benz's electric G-Wagen), Land Rover is banking on familiarity. Terrain modes from combustion models have been retained, and the company has developed its own intelligent traction control system (ITM) to manage torque across all four wheels. The ITM system allows for millisecond-level torque vectoring between wheels, with cross-axle capability and the ability to emulate both two-wheel and four-wheel drive. It replaces traditional mechanical driveline components with software precision, providing finer control in both on- and off-road environments. "We've optimised all of the terrain modes for Range Rover Electric," Mr Owen explained. "It's about making it actually comfortable off-road and reducing driver demand in challenging conditions." The model also includes adaptive thermal management with a proprietary heat pump system designed to improve efficiency and comfort. Land Rover says the system can operate in temperatures as low as -15°C, recovering waste heat to reduce energy consumption by up to 40 per cent compared with the brand's previous electric vehicle, the Jaguar I-Pace. While other manufacturers often borrow EV components from shared platforms, Land Rover's vertically integrated approach reflects its aim to control the Range Rover Electric experience end to end. It may look familiar, but beneath the skin, this is the most technologically advanced model the company has built. With more than 62,000 customers already expressing interest globally, the Range Rover Electric appears to be landing well with buyers looking for electrification without dramatic change. MORE: Explore the Range Rover showroom Content originally sourced from:
