On-board charger(OBC) is a device that convert ac power from any ac source into the practical dc form. It is usually mounted inside the vehicle and it’s main function is power conversion. Hence, on-board chargers provides the advantage of charging the electric vehicle using the power outlet at our homes itself. In addition, it also eliminates the need for buying any extra equipment for power conversion.
The global electric vehicle On-Board Charger (OBC) market is estimated to reach $10.82 billion by 2027, registering a CAGR of 22.4% from 2020 to 2027. With OBCs that on average give 25% higher DC-DC rating and ~30% reduction in charge duration, Electra EV has been developing OBCs which have helped electric mobility applications exceed end-user expectations.
The specifications of the battery charger influence the charging time and battery life. Let us look into detail about an OBC.
Role of on-board charger
The main function of an on-board charger, is to manage the flow of current from the grid to the traction battery. On-board chargers (OBCs) helps in charging the electric vehicles from any source. Hence, electric vehicles do not have to depend on charging stations all the time.
Another function of OBC is that it controls the level of current and voltage at which the battery is charged. There are mainly two types of charging : constant voltage and constant current charging. Even though constant current charging provides high efficiency and high charging speed it can affect the lifespan of the battery. This is due to over-charging. In the case of constant voltage charging, there is a chance that a high amount of current can flow into the battery initially.
The above problem can be solved by charging the battery initially by constant current charging. Then after reaching a certain amplitude, the battery is charged using constant voltage charging. This charging strategy is the most important role of an on-board charger.
On-board charger in different charging stations
|ESVE||Charging level||AC Supply specification||Power rating||Time taken to charge a 24kWh battery pack (approx.)|
|AC charging station||Level 1 – residential applications||Single Phase- 120/230 V and 12 to 16 A||1.44 kW to 1.92 kW||17 hrs|
|AC charging station||Level 2- Commercial applications||Split Phase – 208/240 V and 15 to 80 A||3.1 kW to 19.2 kW||8 hrs|
|DC charging station||Level 3- Fast charging||Single Phase- 300/600 V and approx. 400 A||120 kW to 240 kW||30 min|
Role of OBC in AC charging
In AC charging level 1 and level 2, the AC power from the grid is converted to DC power by the OBC to charge the battery via the Battery Management System(BMS). The voltage and current regulation is performed by the OBC. In addition, the disadvantage of AC charging is as its charging time increases, the power output becomes low.
The charging rate, or required input current, is determined by the EV itself in AC chargers. Because not all electric vehicles (EVs) require the same amount of input charging current, the AC Charger must communicate with the EV to determine the required input current and establish a handshake before charging can commence. This communication is referred to as Pilot wire communication. The Pilot wire identifies the type of charger attached to the EV and sets the OBC’s required input current.
Role of OBC in DC charging
In DC fast charging or Level 3 charging, the AC power from the grid is directly supplied to the Battery Pack. As shown in the figure above, we can see that there is a AC/DC converter in-built in the DC charger itself. Hence it eliminates the need for OBC in this level of charging. Therefore, this helps in reducing the charging time. The EVSE is arranged in stacks to deliver high current because a single stack will not be able to supply high current. Hence, there is no role of OBC in DC Charging.
Types of on-board charger
There are mainly two types of on-board chargers :
- Single phase On-board Charger
- Three phase On-board Charger
This classification is based on the number of phases it can use. The output of a standard single phase OBC is 7.2-7.4 kWh. While, that of a three-phase OBC is 22kWh. As a matter of fact, the OBC is able to detect which type of input it can accept. When connected to only one phase, the power that this on-board charger can tolerate is 110 – 260 V AC (and 360 – 440V in the case of using three phases). The battery receives a voltage between 450 and 850 volts as an output.
Working of an on-board charger
In OBCs using a rectifier, high power AC input is converted to DC power and provides Power Factor Correction. To boost the power factor to unity, a power factor correction (PFC) circuit removes harmonic distortion in the supply current and provides a current waveform that is close to a basic sine wave. This section of the charger determines whether it can use one, two, or all three alternating current phases. In addition, the DC/DC converter must isolate the power grid from the HV dc bus and the HV dc bus from the LV dc bus for safety reasons.
The second phase receives the 700V output voltage. The resultant DC signal is chopped into a square wave, that drives a transformer. This further provides the required DC voltage. An isolated CAN bus can be used to monitor and control the entire system. Digital isolators and digital isolators with integrated DC/DC power converters are used to isolate the CAN. Finally, the required voltage is supplied to the battery.
Design Considerations of OBCs
The factors that needs to be considered before designing the OBCs:
- The AC input and the required output level
- The maximum power the battery pack can withstand
- Temperature cooling and space reduction
- Charging time
- Rectification of AC signal and Power Factor Correction (PFC)
- Communication between the EV and EVSE
- Safe isolation between power source and battery
Growth of OBC in the automotive industry
During the period 2020-2025, the worldwide automotive on-board charger market is expected to grow at a CAGR of around 30%.In the projected term, growing sales of electric vehicles, strict pollution laws, developments in battery technology, and improved charging infrastructure are expected to boost demand for automotive on-board chargers. Electric passenger vehicles are already being adopted in developed nations, and new startups and significant players in the EV sector are aiming to launch their own new electric models in the next years.
Studies and developments are focusing on developing more efficient and light weight on-board chargers. Because development can help in the advancement of electric vehicle industry. Many established and emerging countries have framed their green mobility plans, which include prohibiting diesel vehicles and providing incentives to buyers of electric vehicles. By 2030, India intends to prohibit all diesel-powered vehicles off the roadways.
Because of the presence of new startups and big automotive electronics manufacturers, the global automotive on-board charger market is fragmented and contains multiple active participants. Some of the major manufacturers are:
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