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Charging pile manufacturer - Golong

Established in 2015, Golong Technology Co., Ltd. has quickly risen to a leading position in the realms of Internet, Internet of Things, and innovative payment systems. Our journey began with pivotal advancements in public transportation payment aggregation systems, and today, we are at the forefront of the EV charging pile industry.

As a premier manufacturer and exporter of charging piles, Golong is dedicated to delivering cutting-edge solutions that meet the highest standards of safety and efficiency. Our Euro standard dual-gun DC charging post exemplifies this commitment, offering dual charging ports, CCS2 and CHAdeMO, to cater to diverse needs. This state-of-the-art system ensures reliable and efficient charging, while real-time status monitoring and QR code payment support enhance user convenience.

Golong’s product suite extends to the AC EV charger range, designed to provide flexible and adaptable charging options for varying requirements. Our AC EV chargers are engineered with precision, ensuring seamless integration with existing infrastructure and a robust charging experience.

In our pursuit of global expansion, Golong remains steadfast in our mission to export high-quality charging piles worldwide, enhancing the EV ecosystem with our innovative technology. Join us on the journey to a sustainable future with Golong’s advanced EV charging solutions.

Charging pile station

  • Charging Pile Station(direct current)

    Charging Pile Station(direct current)

    The Euro standard dual-gun DC charging post offers two charging ports, CCS2 and CHAdeMO. Providing safe, reliable and efficient charging while monitoring the status and Supports QR code sweeping for payment. 

     

    moq: 1PCS

What Is charging pile

● Introduction



As electric vehicles (EVs) are becoming increasingly popular, the infrastructure required to support them, such as charging piles, is also evolving. Charging piles are integral components of EV charging stations, and their primary function is to deliver electrical energy to the vehicles' batteries. In recent years, advancements in technology have made charging piles more intelligent, efficient, and secure, thereby contributing to the growth and acceptance of electric vehicles.

● What is a Charging Pile?



A charging pile, sometimes referred to as a charging post or charging station, is a device designed to supply electric energy to recharge EV batteries. These units can be found in various locations, including residential areas, commercial spaces, highways, and public places. There are generally three types of charging piles: slow (Level 1), fast (Level 2), and rapid (Level 3 or DC fast chargers). Each type serves different needs, ranging from overnight home charging to quick top-ups at public stations.

● The Technology Behind Intelligent Charging Piles



○ Microcontroller Units (MCUs)



One of the key technological advancements in charging piles is the incorporation of

○ Microcontroller Units (MCUs)

. MCUs are at the heart of intelligent charging management. They play a crucial role in monitoring and controlling the charging process by interfacing with the EV’s onboard systems. The MCU can read vehicle information, adjust the charging power based on the battery’s status, and optimize the use of electricity, especially during peak and valley times, making the process more efficient and cost-effective.

○ Real-time Recognition



Modern charging piles often come equipped with real-time recognition capabilities. Using advanced cameras and algorithms, these systems can recognize vehicles approaching the charging station and authenticate users. For example, license plate recognition systems can determine whether a vehicle is registered and authorized to use the station. If the authentication is successful, the charging process begins automatically; otherwise, access is denied, enhancing security and user experience.

○ Sensor Fusion



Sensor fusion is another significant feature of intelligent charging piles. It involves integrating data from multiple sensors, such as those measuring temperature, current, voltage, and humidity, to ensure precise control and monitoring. This multi-sensor approach helps optimize the charging process by adjusting parameters in real-time based on the sensor readings. For instance, if the temperature sensor detects overheating, the system can reduce the charging power or temporarily halt the process to prevent damage.

● Anomaly Detection and Response



One of the hallmarks of smart charging piles is their ability to detect anomalies. By using pre-defined thresholds or machine learning models, the system can identify irregularities like overvoltage, overcurrent, or abnormal temperature levels. When an anomaly is detected, the system can take immediate corrective actions, such as interrupting the charging process or sending alerts to maintenance personnel, thereby ensuring the safety and reliability of both the charging station and the vehicle.

● Benefits of Intelligent Charging Piles



○ Efficiency and Energy Savings



The smart features embedded in modern charging piles contribute significantly to energy savings. By optimizing the charging process and adjusting power usage based on real-time data, these systems can reduce energy waste and lower operational costs. The ability to use off-peak electricity rates further enhances cost-efficiency, making electric vehicle charging more affordable for consumers.

○ Enhanced User Experience



The integration of real-time recognition, sensor fusion, and anomaly detection creates a seamless and user-friendly charging experience. Authorized users can quickly access the charging service without manual intervention, and the system’s ability to promptly address issues ensures minimal downtime and high reliability.

○ Contribution to Smart Cities



Intelligent charging piles are a critical component of smart city ecosystems. They not only support sustainable transportation solutions but also integrate with other smart city functions such as smart lighting and interactive signage. This synergy promotes the modernization and sustainability of urban environments, providing citizens with a more convenient and comfortable living space.

● Conclusion



Charging piles are evolving from simple electric supply points to sophisticated smart devices that play a vital role in the growth of electric vehicles and smart cities. Through the integration of MCUs, real-time recognition, sensor fusion, and advanced anomaly detection, these intelligent charging systems offer numerous benefits, including enhanced efficiency, improved user experience, and significant contributions to sustainable urban development. As technology continues to advance, the future of charging piles looks promising, paving the way for broader acceptance and use of electric vehicles worldwide.

FAQ about charging pile

What is a charging pile?

● Introduction to Charging Piles



As the global shift towards sustainable energy sources gains momentum, electric vehicles (EVs) are increasingly becoming a pivotal part of our transportation ecosystem. A crucial element that bolsters the adoption of EVs is the availability and convenience of charging infrastructure. Among the different components of this infrastructure, the charging pile stands out for its versatility and essential role in the day-to-day charging of electric vehicles.

● What is a Charging Pile?



A charging pile functions similarly to a gas station pump but for electric vehicles. These devices are fixed installations, either on the ground or on a wall, that deliver electrical energy to EVs through a specialized charging interface. They are designed to be deployed in various settings, including public buildings, residential parking lots, and public electric car charging stations. Charging piles can service different types of electric vehicles and cater to multiple voltage levels, making them highly adaptable and efficient.

● Technical and Functional Aspects



The charging pile is connected directly to the alternating current (AC) power grid at its input end. The output end is equipped with charging plugs specifically designed to fit different brands and models of electric vehicles. Charging piles generally offer two modes of operation: regular charging and quick charging. Regular charging usually employs lower voltage levels and is ideal for overnight or long-duration charging sessions. Quick charging, on the other hand, uses higher voltage (often direct current, or DC) to enable faster energy transfer, thereby reducing the waiting time significantly.

● User Interaction and Convenience



One of the most user-friendly features of the charging pile is its human-computer interaction interface. This interface allows users to swipe a specific charging card to initiate the charging process, select the charging mode, set the charging duration, and even print cost data. The display screen on the charging pile provides real-time information such as the amount of charge delivered, the cost incurred, and the time elapsed. This level of transparency and control ensures a hassle-free and informed charging experience for the user.

● Comparative Analysis with Charging Stations



While both charging stations and charging piles serve the same fundamental purpose of charging electric vehicles, they operate at different scales and scopes. Charging stations are comprehensive facilities that may comprise multiple charging piles, along with additional systems for power distribution, battery scheduling, and monitoring. These stations often provide a range of services, including regular charging, quick charging, and even battery replacement. Charging piles, in contrast, are singular units focused solely on the task of charging, though they form an integral part of the larger charging station setup.

● Modern Applications and Future Prospects



With the rapid advancement in electric vehicle technology and the growing emphasis on green energy solutions, charging piles are set to become even more sophisticated. Innovations such as smart charging, automated payment systems, and enhanced connectivity through IoT are expected to transform the landscape of EV charging. The growing network of charging piles will significantly contribute to the convenience and feasibility of owning and operating electric vehicles, thus accelerating the global transition towards more sustainable transportation solutions.

● Conclusion



Charging piles play a vital role in the ecosystem of electric vehicle infrastructure. They are versatile, user-friendly devices designed to meet the diverse charging needs of modern electric vehicles. By providing reliable and efficient charging solutions, charging piles help facilitate the broader adoption of electric cars, thereby contributing to a cleaner, more sustainable future. As technology continues to evolve, charging piles will undoubtedly see enhancements that further improve their performance and accessibility, solidifying their position as a cornerstone of the EV revolution.

What is the difference between charging station and charging pile?

Understanding the nuances of the electric vehicle (EV) infrastructure is crucial in the era of rapidly expanding EV adoption. Two frequently mentioned terms are "charging station" and "charging pile," and while they are sometimes used interchangeably, they possess distinct characteristics and functionalities that are worth elucidating.

The Basics of Charging Stations

Charging stations serve as the comprehensive facilities where electric vehicles can recharge their batteries. These installations often exist in public spaces such as parking lots, residential complexes, and commercial premises. A charging station typically includes multiple components: the ac ev charger, electric supply infrastructure, user interface, and sometimes additional features such as lighting or protective shelters. It is designed to provide a safe, convenient, and efficient charging experience, catering to various charging speeds and connector types.

Anatomy and Functionality of Charging Piles

In contrast, a charging pile is a specific physical device within the charging station responsible for the direct interfacing and transfer of electrical energy to the EV. The charging pile encompasses the hardware for connecting to the vehicle, often through an ac ev charger, which converts and controls the electric current suitable for the vehicle's battery system. It predominantly focuses on the mechanical and electrical aspects of the charging process itself, devoid of the broader infrastructural elements present in a full-fledged charging station.

Comparative Analysis

Scope and Deployment

The key difference lies in their scope and deployment. Charging stations represent the broader ecosystem designed for facilitating EV charging, encompassing various technological and supportive infrastructures. These stations often include multiple charging piles to accommodate numerous vehicles simultaneously, ensuring usability and reliability. On the other hand, a charging pile is a singular, functional entity within this ecosystem, emphasizing the direct interaction and energy transfer to the vehicle.

User Interaction and Experience

Another aspect of differentiation is seen in user interaction and experience. A charging station tends to offer a more user-friendly interface, integrating digital screens, apps, and payment systems, ensuring a smoother and more interactive experience for EV owners. It often includes ac ev chargers that can handle different charging standards and power levels. Conversely, the charging pile is more utilitarian, focusing on the technical aspects of delivering electricity, although it might integrate some user interface elements, depending on the design.

Maintenance and Management

From a maintenance and management perspective, a charging station requires holistic oversight, involving regular checks of the electrical infrastructure, software updates, and general upkeep of the premises. It demands a more substantial investment in terms of both initial setup and ongoing operational costs. In comparison, a charging pile, due to its limited functional scope, simplifies maintenance, focusing predominantly on the device’s operational efficiency and reliability.

Conclusion

In conclusion, while charging stations and charging piles are integral components of the EV charging infrastructure, they inhabit different realms of functionality and user engagement. Charging stations represent the overarching facilities that host multiple charging units and provide a user-friendly and comprehensive charging environment. On the other hand, charging piles are the specific devices within these facilities, focusing on the precise delivery of electrical energy to vehicles through components like the ac ev charger. Understanding these distinctions is essential for stakeholders in the EV ecosystem, from manufacturers and installers to end-users, ensuring an informed and efficient approach to EV charging solutions.

What is charging pile equipment?

Charging pile equipment is an essential component of the modern electric vehicle (EV) infrastructure, serving as the bridge between the power grid and electric vehicles. This sophisticated technology enables EVs to recharge their batteries efficiently and safely, making them a cornerstone of the transition towards greener and more sustainable transportation solutions.

Charging Pile Equipment: An Overview

Charging pile equipment, commonly known as an EV charger, is designed to supply electric energy to the battery of an electric vehicle. There are various types of charging pile equipment, primarily categorized into alternating current (AC) chargers and direct current (DC) chargers. AC chargers are typically found in residential or semi-public settings, suitable for longer charging periods, while DC chargers are more prevalent in public charging stations, offering rapid charging capabilities.

AC EV Chargers

AC EV chargers are the most common type of charging equipment, used extensively in residential setups and places where vehicles are parked for extended periods, such as workplaces or shopping malls. These chargers convert the AC power from the grid into the DC power required by the vehicle's battery through an onboard charger within the vehicle. AC chargers are typically slower, with charging speeds ranging from 3.7 kW to 22 kW, depending on the specific model and installation. Despite their slower charging rate compared to DC chargers, AC EV chargers are favored for their cost-effectiveness and convenience for overnight charging.

DC Fast Chargers

In contrast, DC fast chargers deliver electricity directly to the vehicle's battery, bypassing the need for an onboard charger. They convert AC power from the grid into DC power within the charging station itself, enabling much higher power delivery and significantly faster charging times. These chargers are often found in public charging stations, along highways, and in urban areas where quick turnaround times are essential. DC fast chargers can deliver power ranging from 50 kW to 350 kW, allowing an EV to reach 80% charge in as little as 20-30 minutes, depending on the vehicle and charger capabilities.

Components and Features

Charging pile equipment comprises several critical components, including the power supply unit, charging cable, connectors, and user interface. The power supply unit ensures a steady and regulated flow of electricity to prevent overloading and damage to the vehicle's battery. The charging cable and connectors must adhere to standardized specifications to be compatible with different vehicle models and ensure safety. The user interface, often featuring touchscreens or mobile app integration, facilitates user interaction, allowing them to monitor the charging process, make payments, and receive notifications.

Safety and Standards

Safety is paramount in the design and operation of charging pile equipment. Robust safety mechanisms are integrated to protect both the user and the vehicle. This includes features such as ground fault protection, overcurrent protection, and temperature monitoring. Compliance with international standards and certifications ensures that the equipment meets stringent safety, interoperability, and performance benchmarks.

Future Prospects

As the adoption of electric vehicles continues to rise, the demand for efficient and accessible charging infrastructure will grow concomitantly. Innovations in charging technologies, such as wireless charging and vehicle-to-grid (V2G) systems, are set to further enhance the capabilities of charging pile equipment. The evolution of charging infrastructure will be pivotal in supporting the widespread adoption of electric vehicles, contributing to the reduction of carbon emissions and fostering a sustainable future.

In conclusion, charging pile equipment plays a vital role in the electric vehicle ecosystem, facilitating reliable and efficient recharging of EV batteries. With advancements in technology and increasing adoption, these systems are poised to support the growth of electric mobility and the broader objectives of environmental sustainability.

Should I only charge my electric car to 80%?

Charging an electric vehicle (EV) to the optimal level is a crucial aspect of maximizing battery health and lifecycle. While many EV owners might be tempted to charge their vehicle to 100%, it is generally advised to adhere to an 80% charge limit for regular use. This approach not only extends the longevity of the battery but also enhances overall vehicle performance.

● The Science Behind Battery Charging



The lithium-ion batteries that power most electric vehicles are highly sensitive to their charge and discharge cycles. When a battery is charged to its full capacity, it undergoes stress that can accelerate degradation. This is primarily due to the formation of lithium metal tendrils, known as dendrites, which may cause short circuits. Moreover, a full charge generates higher temperatures, leading to side reactions within the electrolyte that precipitate the loss of active lithium ions. Consequently, consistent charging to 100% can markedly reduce the battery's state of health (SoH) over time.

○ Buffer Systems in Modern EVs



To alleviate the adverse effects of full charging, numerous automakers integrate buffer systems within their EVs. These systems display a full charge on the dashboard while maintaining a safe buffer that prevents the battery from actually reaching its extreme limits. This reserve serves as a protective measure against rapid degradation, ensuring the battery's longevity. However, these in-built buffers do not entirely negate the potential harm caused by regular full charges, making it prudent to avoid reaching 100% whenever possible.

● Optimal Charging Practices



For daily commutes and routine use, keeping the charge level between 30% and 80% is widely recommended. This range minimizes the strain on the battery and reduces the depth of discharge (DoD), thereby prolonging its lifecycle. Depth of discharge refers to the percentage of the battery that is depleted before recharging it. Studies indicate that a lower DoD significantly extends the number of cycles the battery can endure. For instance, cycling to 50% DoD can sustain the battery's capacity four times longer than a 100% DoD cycle, even with buffer systems in place.

○ Practical Application of Charging Limits



Implementing these optimal charging practices is facilitated by the use of an AC EV charger. These chargers offer customizable settings that allow users to set a maximum charge limit, ensuring that their EVs do not exceed the 80% threshold. The convenience of an AC EV charger also extends to the ability to schedule charging sessions during off-peak hours, which can result in cost savings and reduced grid strain.

● The Risks of Full Discharge



On the opposite end of the spectrum, consistently discharging the battery to 0% is equally detrimental. A fully depleted battery requires meticulous recovery and, if left unused, might self-discharge to a point where it can no longer be revived. Thankfully, modern EVs are equipped with battery management systems (BMS) that prevent complete discharge by maintaining a buffer of 5-10%. Nevertheless, it is best to recharge the battery well before it hits this critical low to maintain its health and avoid potential recovery issues.

● Conclusion



In conclusion, to ensure the longevity and performance of an electric vehicle's battery, it is advisable to maintain a charge level between 30% and 80% for regular use. While the advanced buffer systems in modern EVs provide some protection against the extremes of full charge and discharge, consistently charging to 100% or allowing the battery to deplete completely should be avoided. Utilizing an AC EV charger with customizable settings can conveniently facilitate optimal charging practices, ultimately safeguarding your EV's battery for years to come.

Can I set my EV charger to stop at 80%?

When it comes to charging your electric vehicle (EV), the question of whether you can set your EV charger to stop at 80% often arises. Understanding the advantages of adhering to this practice can greatly enhance both your vehicle's performance and your overall driving experience.

Why Stop at 80%?



● Healthier Battery and Cost Efficiency



One of the primary reasons for setting your EV charger to stop at 80% is to promote a healthier battery lifespan. Most EVs are equipped with Lithium-ion batteries, which, despite their numerous advantages, do degrade over time. Constantly charging to 100% and then discharging places considerable stress on the battery cells. By stopping at 80%, you reduce this strain, prolonging the battery's overall life. Additionally, a healthier battery means fewer replacements, ultimately saving you money in the long run.

● Enhanced Braking System Efficiency



Another significant benefit of capping your charge at 80% involves the efficiency of your EV’s regenerative braking system. This system converts the kinetic energy produced during braking into stored energy for the battery. If your battery is always near full capacity, it limits the amount of energy that can be stored from regenerative braking. By maintaining a bit of empty space in the battery, you ensure that this energy can be effectively utilized, potentially extending the lifespan of your braking system and enhancing vehicle efficiency.

● Faster Charging Times



Charging speed is another crucial factor to consider. The process of charging an EV doesn’t happen at a constant rate; it varies depending on the battery's state of charge. As the battery approaches full capacity, the charging rate tends to slow down due to the increased difficulty in fitting more electrons into the already crowded space. By capping the charge at 80%, you avoid this slow phase, allowing for faster, more efficient charging sessions. This can be particularly advantageous during short stops when you need a quick recharge to get back on the road.

Practical Considerations



● Setting the Charge Limit



Many modern EVs offer the functionality to set a maximum charge limit, making it easier to adhere to the 80% rule. Consult your vehicle’s manual or manufacturer to see if this feature is available in your model. By setting this limit, you can ensure that your vehicle charges up to the desired level without manual monitoring.

● Exceptions to the Rule



While the 80% rule is generally advisable for daily use, there are circumstances where charging to 100% may be necessary. For instance, if you are planning a long trip and need the extra range, fully charging your battery may be justified. However, it’s important to treat this as an exception rather than a standard practice to avoid long-term degradation of your battery's health and performance.

Making the Most of Public Charging Infrastructure



When utilizing public charging stations, it’s essential to keep the 80% rule in mind. Many public chargers are conveniently located near facilities where you can relax or grab a bite while your vehicle charges. By aiming for an 80% charge, you can ensure that your vehicle is ready more quickly, allowing you to continue your journey with minimal delay.

In conclusion, setting your EV charger to stop at 80% is a practical and beneficial approach to maintaining your vehicle's battery health, optimizing regenerative braking, and ensuring faster charging times. Whether you’re using a home charger or public charging infrastructure, adopting this practice can lead to a more efficient and cost-effective EV experience.

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