As technology continues to rapidly advance, the concept of wireless charging is gaining popularity. This relatively recent innovation utilizes electromagnetic technology, and in this blog post, we will explore its brief history, and functionality, as well as its benefits, and drawbacks.
What is wireless charging?
Inductive charging, commonly known as wireless or cordless charging, is a charging method that utilizes an electromagnetic field to transfer energy between two objects without the need for wires. This technology employs electromagnetic induction to generate electricity across a magnetic field, allowing a device to be charged wirelessly via a charging station. The energy is then transmitted through an inductive coupling to an electronic device, which uses the energy to either charge its batteries or power the device. The Qi wireless charging standard is an example of this technology, which has enabled wireless charging for smartphones.
History of wireless charging
At first, scientists aimed to transmit power through radio waves, which were initially predicted by James C. Maxwell in 1864. Nikola Tesla was also a firm believer in the feasibility of wireless power transfer. Nevertheless, his Tesla Tower experiment failed due to the power diffusing in various directions. In the 1960s, the focus shifted to investigating the use of microwaves for power transmission.
Back in 1972, Professor Don Otto of the University of Auckland worked on developing a vehicle powered by induction, utilizing transmitters installed on the road and a receiver on the vehicle. However, it was not until 1977 that John E. Trombly obtained a patent for an electromagnetically coupled battery charger. This patent primarily focused on charging batteries for miners’ headlamps. Nevertheless, the first application of inductive charging used in the US is attributed to J.G. Bolger, F.A. Kirsten, and S. Ng, who, in 1978, developed an electric vehicle powered by a system operating at 180 Hz with 20 kW.
After the electric vehicle experiment, further progress was made in the field of inductive charging. In California, a bus was developed that used inductive charging technology. Similar work was also being done in France and Germany during the 1980s. A significant breakthrough occurred in 2006 when MIT began using a resonant coupling, which allowed scientists to transmit a substantial amount of power over short distances without radiation. This development paved the way for commercial applications of inductive charging.
Relatively recent times have seen the rise of several organizations working in this field; they mainly work towards creating standards for inductive charging. Think about the setting up of the Wireless Power Consortium (WPC); it was established in 2008, and in 2010 they came up with the Qi standard. Soon after, in 2012, the Alliance for Wireless Power (A4WP) and the Power Matter Alliance (PMA) were established. Japan came up with the Broadband Wireless Forum (BWF) in 2009, and it established the Wireless Power Consortium for Practical Applications (WiPoT) in 2013. The Energy Harvesting Consortium (EHC) was also founded in Japan in 2010. The next year (2011) saw Korea set up the Korean Wireless Power Forum (KWPF).
Wireless charging standards
Before we go into how wireless charging works, let’s take a look at the meaning of a wireless charging standard. Standards refer to the different set operating systems with which devices are compatible. There are two major standards: Qi and PMA. Although they work in a similar fashion, they have different transmission frequencies and connection protocols. Due to this, appliances compatible with one standard may not be compatible with the other. That said, there are devices compatible with both standards.
Qi standard: Developed by the Wireless Power Consortium, Qi is an open interface standard where wireless power is transferred using inductive charging over distances of up to 4 cm (1.6 inches). The system uses a charging pad and a compatible device, which is placed on top of the pad and the charging takes place via resonant inductive coupling. Initially released in 2008, the Qi standard has been incorporated into more than 140 smartphones, tablets, and other devices. Mobile manufacturers making devices compatible with this standard include Apple, Asus, Google, HTC, Huawei, LG Electronics, Motorola Mobility, Nokia, Samsung, BlackBerry, Xiaomi, and Sony.
PMA standard: Founded by Procter & Gamble and Powermat Technologies in 2012 to advance a suite of standards and protocols for wireless power transfer, Power Matters Alliance (PMA) was a global, not-for-profit, industry organization that got merged with Alliance for Wireless Power (A4WP) in 2015 to form AirFuel Alliance. The goal of this body was to network with technology companies to guarantee consumers interoperable devices that make use of wireless power technology. Denoted by the electron “P”, the PMA interface standard described analog power transfer (inductive and resonant), digital transceiver communication, cloud-based power management, and environmental sustainability. PMA draws members from companies across a wide spectrum spanning the mobile device ecosystem and thus includes handset providers, service providers, chipset suppliers, manufacturers, test labs, and public establishments.
How does wireless charging work?
Wireless or inductive charging works on the same principle as induction cooktops, i.e. using electromagnetic induction, which generates a voltage across a conductor placed in a changing magnetic field or a conductor moving through a stationary magnetic field.
An induction charger typically comprises two primary induction coils. One is encased in the charging base or the mat; it is the component that produces an alternating current (AC) from within the base. The other is located in the portable device in need of a charge, say a smartphone, tablet, etc. The coil could be in the form of a pad that clips to your phone, a circuit embedded inside the phone, or a replacement battery cover with a built-in charging coil that gets connected to the charging socket. Together, these two coils form an electrical transformer.
In the case of a mobile being charged wirelessly, this is what happens: when the power supply to the charging base/plate is switched on, AC flows through it and creates an electromagnetic field (a changing magnetic field) around the primary coil. With the secondary coil or the receiver coil (that is housed in the smartphone) coming in contact with the former, an electric current is generated within the coil. The AC flowing through the coil in the smartphone is converted into DC (Direct Current) by the receiver circuit. The DC generated in this way is used to charge the battery of the smartphone.
Applications of wireless charging
Applications of wireless charging can be classified into two categories: low power and high power. While low-power applications usually work for small consumer electronic devices like cell phones, handheld devices, some computers, and similar devices which charge at power levels below 100 watts, high-power wireless charging typically refers to inductive charging of batteries at power levels above 1 kilowatt. The biggest application area would be charging electric vehicles, where inductive charging makes for an efficient, cordless, and automated option for plug-in charging. Power levels of these devices vary between 1 kilowatt to 300 kilowatts or higher. Such high-power inductive charging systems generally make use of resonated primary and secondary coils.
In terms of examples of devices using wireless charging, there is a wide variety out there today, starting from Oral-B rechargeable toothbrushes by the Braun company (that have used inductive charging since the early 1990s) right up to mobile phones by Nokia, and Samsung, Apple, and Google and of course, electric vehicles.
A majority of smartphone manufacturers such as Apple and Samsung have adopted the Qi wireless charging standard. Samsung and other companies have begun toying with the idea of “surface charging”, which is where an inductive charging station is built into an entire surface such as a desk or table. On the other hand, companies such as Apple are opting for dock-based charging platforms; which include charging pads and disks that have a much smaller footprint.
Advantages and disadvantages
Like most technologies, wireless charging comes with a host of advantages and disadvantages. Here we take a look at both.
a. For starters, wireless charging typically means protected connections, since there is no corrosion when the electronics are enclosed and thus away from water or oxygen. There’s also a lower risk of electrical faults such as short circuits due to insulation failure, especially when connections are made or broken frequently.
b. Wireless charging adds to a device’s durability as there is no need to keep plugging and unplugging the device and thus much less wear and tear on the socket of the device and the attached cable.
c. This technology helps minimize infection risks. So in an embedded medical device, power is transmitted through a magnetic field passing through the skin, thereby avoiding infection risks that come with wires penetrating the skin.
d. Automated high-power inductive charging of electric vehicles is known to pave the way for driving range extension.
e. Doing away with charging cables offers more convenience and greater aesthetic quality.
f. With no dependence on people to plug or unplug a device thanks to automatic wireless charging, there’s higher reliability.
g. Autonomous vehicles, typically electric vehicles, rely on autonomous electric charging. Automatic operation of inductive charging shall help solve this problem, and now the vehicle can theoretically run indefinitely.
h. Inductive charging of electric vehicles at high power levels allows charging of electric vehicles while in motion (also known as dynamic charging).
Several disadvantages have been observed among low-power (i.e., less than 100 watts) inductive charging devices.
a. Such devices take 15 percent longer to charge even when the power supply is the same; this slow charging is caused by lower efficiency.
b. Wireless charging requires drive electronics and coils in both device and charger, thus adding to the complexity and the manufacturing costs.
c. When a mobile device is connected to a cable, it can be moved around (although within a certain range) and used even as it gets charged. But with most implementations of inductive charging, the mobile device has to be left on a pad to charge, and thus can’t be moved around or easily operated on while charging. In the case of some standards, charging can be done at a distance, but only when there is nothing in between the transmitter and receiver.
d. While some devices now support multiple standards, many of them are not compatible with different inductive chargers.
e. Wireless charging is said to be not as efficient as direct charging. There is a greater possibility of the phone being charged getting too hot. Continuous exposure to heat can in turn lead to battery damage.
The Road Ahead
Thanks to the use of ultra-thin coils, higher frequencies, and optimized drive electronics, transfer losses have been reduced to a great extent today. This had led to the rise of more efficient and compact chargers and receivers, facilitating their integration into mobile devices or batteries with minimal changes required.
Significant developments are being seen in the use of wireless charging in the medical sector and for electric vehicles. In the former area, researchers are looking at being able to charge implants and sensors long term that is situated beneath the skin. They have been able to print wireless power-transmitting antennae on flexible materials that can be placed under the patient’s skin. This means that under-skin devices that aim to monitor the patient status could have a long-term life and offer long observation or monitoring periods thus resulting in better diagnosis from doctors. These devices could also make charging devices such as pacemakers easier on the patient rather instead of exposing a portion of the device by pushing it through the skin to allow corded charging. In other words, headway in this field would make a completely implanted device quite safe for the patient. Of course, the technology will be subject to approval following extensive research on its safety. It’s also important to note that the high-speed power transfer achieved with the flexible antennas in these medical-based applications needs to be examined for its broader implications.
Another area with noteworthy experimentation is one where a predefined path or conductors would transfer power across an air gap using wireless technology and charge the vehicle on a predefined path such as a wireless charging lane. Sweden, for instance, opened the world’s first electrified road last year. A 1.2-mile route, between Stockholm Arlanda airport and a logistics site, the road is said to actively charge cars and lorries as they travel along it using an innovative energy transfer system.
However, a key issue preventing such roads from becoming widespread is the initial cost associated with installing the required infrastructure, especially since it that would benefit only a small percentage of vehicles currently on the road. Another issue is keeping track of how much power each vehicle is consuming from a wireless charging lane. Faced with no clear commercial way to monetize this technology, many governments have not been keen to spend on building such lanes as part of their public works packages.
That said, large-scale wireless charging might just become a reality: there are wireless mats out there already that allow electric vehicles to be charged without a corded connection while parked on such a mat. Although it must be pointed out that these leading electric vehicles manufacturers, such as Tesla, Toyota, and BMW are also looking to design new heat dispersion methods by which they can do away with the excess heat generated between the two charging surfaces.