Application and configuration analysis of electric muck transfer equipment in plateau railway tunnel: a case study in southwest China

The burgeoning development of railway construction in plateau regions of southwest China necessitates innovative and environmentally sustainable approaches, particularly in the realm of tunnel construction, where the transfer of muck poses significant operational and environmental challenges. This research, pivoting around the application and configuration of electric muck transfer equipment in plateau railway tunnels, seeks to dissect the potentialities and impediments of transitioning from conventional diesel-powered machinery to electric alternatives, with a spotlight on mitigating environmental impacts and enhancing operational efficiency. Through an analytical lens, the study employs a case study methodology, leveraging data and insights from existing electric equipment models and their applications, provided by major manufacturers in China, to weave a comprehensive narrative around the practicalities, specifications, and challenges embedded in the adoption of electric machinery in plateau environments. The findings unveil a nuanced landscape, where the environmental and operational advantages of electric equipment are juxtaposed against a backdrop of technological, financial, and infrastructural hurdles, thereby crafting a complex tapestry of opportunities and challenges. The research further extrapolates policy recommendations and practical guidelines, advocating for a harmonized amalgamation of governmental policies, technological advancements, and strategic planning to navigate through the identified challenges and optimize the integration of electric equipment in tunnel construction practices. Envisaging future research pathways, the study underscores the criticality of perpetuating technological innovations, policy adaptations, and interdisciplinary research to further refine and enhance the application of electric muck transfer equipment in plateau railway tunnel projects, thereby contributing to the broader narrative of sustainable construction practices in challenging terrains.


Requirements of sustainable development concept
In the wake of China's commitment to peak its carbon emissions before 2030 and achieve carbon neutrality before 2060, known as the 'Dual Carbon' targets 21,22 , the nation has been steering its industries towards more sustainable practices.The Ministry of Industry and Information Technology, in 2020, initiated an action plan to expedite the electrification of public sector vehicles, including construction machinery and heavy trucks, thereby aligning with the national agenda to mitigate carbon emissions.Table 1 encapsulates a series of policies and regulations, reflecting China's strategic approach towards embracing green and low-carbon technologies across various sectors, including transport and manufacturing.These policies not only underscore the importance of adopting new energy and clean energy vehicles but also emphasize enhancing charging infrastructure and promoting green products and technologies 23 .
The transition to electric equipment in construction, especially in tunneling operations, is further necessitated by the changing demographics of the Chinese labor force 24 .With an aging population and increasing labor costs, there is a growing need for more efficient, less labor-intensive construction methods.Electric muck transfer equipment offers a solution to these challenges, providing a cleaner, safer, and more sustainable alternative to traditional diesel-powered machinery 25 .While acknowledging the significant strides made in electric vehicle technology and infrastructure, it's crucial to place electric construction equipment within a context that considers multiple alternatives, including hybrid and hydrogen fuel cells.This study examines electric equipment's viability against such alternatives, considering factors like energy efficiency, environmental impact, and adaptability to plateau conditions.

Plateau climate and environmental limitations
Tunnel construction, particularly in plateau regions, is inherently energy and resource-intensive, leading to significant greenhouse gas emissions 26,27 .A primary source of these emissions is the diesel-powered machinery commonly used in drilling and blasting methods, such as excavators, loaders, and dump trucks.These machines, while efficient at lower altitudes, face operational challenges in plateau environments due to the thin air and low oxygen levels.
At lower altitudes, the abundance of oxygen mitigates the concentration of harmful gases emitted by construction machinery, resulting in relatively lower pollution levels.However, in plateau regions, the situation is markedly different (see Table 2).The reduced oxygen content in the air leads to inefficient combustion in diesel engines, significantly increasing the emission of hazardous gases such as nitrogen oxides, oxygenated hydrocarbons, and particulates 28,29 .This not only poses serious health risks to the construction workforce but also complicates the ventilation requirements in tunnel construction, impacting overall efficiency and safety.
At the same time, the problem of oil machinery and equipment competing for oxygen with front-line workers in the plateau area also cannot be ignored, due to the continuous oxygen consumption of construction personnel and mechanical equipment in the tunnel, the oxygen content in the tunnel at high altitude will gradually decrease with the increase of tunnel footage, as shown in Fig. 1.Excessive hypoxia can lead to physical discomfort, fainting, and even death for workers 32,33 , adding to the strain of long-distance ventilation in the plateau tunnels.

Equipment research and development status Electric muck transfer equipment
The vigorous development of electric vehicles has led to the development of power batteries and electric motors, and has also made it possible to electrify construction machinery.Compared with electric vehicles, electric construction machinery and equipment is still in its infancy 36,37 .Currently, tunnel equipment can be divided into three categories according to their power source: (1) Pure electric equipment: common in secondary lining equipment, such as invert trestle, waterproof board trolley, lining trolley, etc.Such equipment have no requirements on the oxygen content of the air in which they operate and do not pollute the tunnel environment.(2) Diesel-electric hybrid equipment: widely used in advance geological prediction, excavation operation, initial lining, the use of diesel power walking, electric power work.The walking time of such equipment takes up a small proportion compared to the working time, which has a slight effect on the pollution and oxygen consumption in the tunnel.(3) Pure diesel power equipment: common in muck transfer equipment, such as excavators, loaders, dumpers, etc.Such equipment is extra sensitive to oxygen and pressure changes in the working environment, and will produce additional toxic gas due to insufficient fuel combustion, causing serious pollution to the tunnel.In addition, the muck transfer line is still dominated by purely diesel power equipment.Muck transfer operations accounted for approximately half of the total cycle time throughout the drilling and blasting method.Therefore, plateau railway tunnel construction for electric equipment demand, mainly concentrated in muck transfer lines.www.nature.com/scientificreports/However, there is no complete set of electric muck transfer equipment for sale in China, and the research and development of related enterprises is concentrated in the small and medium-sized stage, which cannot cover all the working conditions of the plateau railway for the time being.According to the current status of electric equipment products of major manufacturers in China (see Table 3), it can be found that compared with traditional diesel power equipment, the specifications and models of electric excavators and loaders are relatively simple, while the specifications and models of electric dump trucks are relatively various.

Charging infrastructure
(1) Charging pile Charging infrastructure is an essential supporting guarantee for the efficiency of electric equipment.Currently, the construction technique of fixed charging piles is relatively mature.It is feasible to construct centralized charging stations for electric equipment outside the tunnels and configure high-power double-gun quick charging piles.China has also formulated a series of national, industrial and related corporate standards and norms for charging technology.In the short term, shortening charging times and improving endurance are undoubtedly the technological priorities for the market.
The charging pile has a low construction cost and can be distributed flexibly according to the distribution of vehicles.At the same time, one charging pile can satisfy 3-4 vehicles for a whole day's operation.Depending on the operation conditions of the vehicles at the project site, energy can be replenished by exploiting the waiting time for loading and unloading materials and the rest time of the drivers.Equipped with high-power charging piles, the energy can be replenished by 40-50% in half an hour and the driving endurance of vehicles can be increased by 50-70 km.When the tunneling distance is not lengthy, the charging pile can be fixed outside the tunnel.As the tunneling distance increases, it can be considered to fix the charging pile in the secondary lining area of the tunnel and push forward with the tunneling (see Fig. 2).However, it is necessary to further verify the Table 3. Electric equipment models that have been put into production by major Chinese manufacturers.www.nature.com/scientificreports/reliability of the supporting charging piles in the humid, high temperature and relatively muddy environment of the tunnel and how the structural firmness meets the construction requirements under frequent movement.
(2) Battery swap station Compared with charging facilities, the construction of electricity exchange facilities is relatively in the early stages of development.In May 2020, the power station was included in the Government Work Report for the first time, as an vital part of the improved infrastructure.In July 2020, the Ministry of Industry and Information Technology made it clear that it supports electric switching services and encourages auto companies to develop electric switching models.Later that year, at the Huaneng Yimin coal and electricity open-pit mine, China's first set of electric heavy-duty trucks with intelligent power shift systems went through a 100-day high-intensity trial operation, which started the process of electric energy replacement for China's large construction vehicles (see Fig. 3).
The one-time investment cost of the battery swap station is relatively costly (about five to six million CNY), and it covers a large area (about 150-200 square meters), which requires centralized operation.When the number of battery-swap mode machines exceeds 50, the size economy effect can be generated.The electric-changing mode can be considered in the operation scenarios that require high charging efficiency.

Application and configuration analysis Project overview
As a new product, electric muck transfer equipment is rarely used in the engineering construction sector, and is still in the trial phase in the railway tunnel construction sector 38,39 .The project under study is located in a challenging terrain in the plateau mountainous region of southwest China.This tunnel, a crucial part of the railway network expansion in the region, spans approximately 20 km in length.It features a maximum buried depth exceeding 1000 m and is situated at an average elevation of over 3500 m.These geographical and environmental conditions present unique challenges, including significant variations in temperature, reduced oxygen levels, and complex geological structures.
In this project, electric muck transfer equipment, a relatively new innovation in railway tunnel construction, was employed.The equipment, sourced from mainstream manufacturers, matches the traditional diesel-powered equipment in specifications, performance, safety, and reliability.The construction enterprise adopted electric excavators, loaders, dump trucks, and supporting charging infrastructure, creating a comprehensive demonstration of electric muck transfer in tunnel construction.
The operational cycle of the project typically involves three construction phases every two days.Each phase includes a muck transfer duration of approximately three hours, handling about 260 cubic meters of muck.This translates to an average daily working time of 4.5 h for the muck transfer equipment, with an average daily muck transfer volume of 390 cubic meters, or an hourly rate of 86.67 m 3 /h.
Preliminary observations indicate that the performance of the electric equipment aligns closely with that of traditional diesel-powered machinery.For the purpose of a subsequent economic analysis, we have made certain assumptions: excavators and loaders are considered over a depreciation period of ten years, dump trucks over five years, and battery life is also estimated at five years.These calculations do not take into account the salvage value of the equipment.These parameters are set to construct a framework for a detailed economic analysis, which will be elaborated in the following sections.
The relationship between indicators is shown in Fig. 4.
(1) Equipment input cost (C ei ) C ei is calculated according to the following formula: (1) where q refers to the quantity of equipment purchased and U p refers to the unit price of equipment.
(2) Total equipment input cost (C tei ) Total equipment input cost includes equipment input cost (C ei ), battery replacement cost (C br ) and energy supplement facilities cost (C esf ).Therefore, the total equipment input cost (C tei ) can be expressed as follows: (3) Daily equipment depreciation (DED) DED is calculated according to the following formula: where y represents the years of depreciation.
(4) Amortization of total equipment input cost (AC tei ) AC ei is calculated according to the following formula: where m 1 represents the daily amount of muck transfer.
(5) Working energy consumption cost (C wec ) C wec is calculated according to the following formulas: where P e represents the price of electricity per kilowatt-hour; P f represents the price of fuel per liter; B c represents battery capacity; T v represents tank volume; and E represents endurance.
Among them, formula 6 applies to electric equipment and formula 7 applies to diesel power equipment.According to the general situation of the project, the price of electricity per kilowatt-hour is CNY 0.85 and the price of fuel per liter is CNY 8.00.
(2) where m 2 represents the amount of muck transfer per hour.
(7) Amortization of total cost (AC t ) The amortization of total cost (AC t ) includes amortization of equipment input cost (AC tei ) and amortization of working energy consumption cost (AC wec ).Because the trial period of the equipment is not long, the maintenance cost is not considered in this analysis.Therefore, the Amortization of total cost (AC t ) can be expressed as follows:

Excavator
Table 4 meticulously unfolds a comparative analysis between the electric excavator (XE215E) and its dieselpowered counterpart, each embodying distinct operational and economic characteristics that warrant an in-depth exploration within the context of tunnel construction.

Equipment parameters
The electric excavator, while showcasing a formidable maximum mechanical output power of 215 kW, significantly eclipses the 135 kW of its diesel equivalent, thereby ensuring a potent power delivery without compromising on the intrinsic excavation capabilities, as both models exhibit an identical bucket digging force of 149 kN.However, the electric excavator, with a length of 10,050 mm, surpasses its diesel counterpart by 425 mm, potentially introducing navigational complexities within the restricted confines of tunnel environments, thereby necessitating strategic operational planning to safeguard both efficiency and safety.Moreover, the endurance time of the electric excavator, approximately one-third of the diesel model, demands frequent and strategically planned charging sessions to mitigate potential workflow disruptions.www.nature.com/scientificreports/Economic considerations While the electric excavator necessitates a considerably higher initial investment, approximately 1.55 times that of the diesel variant, its working energy consumption cost is less than 50%, heralding potential long-term operational savings.Despite the initial financial outlay, the electric excavator, over an extended period of use, emerges as a more economically prudent option, with cost amortization approximately 18% lower than the diesel power excavator, thereby presenting a compelling economic narrative for its adoption.

In-depth analysis
The electric excavator, despite its frequent charging requisites, operates with zero emissions, aligning seamlessly with global sustainability initiatives and potentially offering long-term economic and environmental dividends, especially in protracted projects.The frequent charging requirements necessitate astute strategic planning to seamlessly integrate charging sessions into the operational workflow, thereby minimizing disruptions and adhering to project timelines.Furthermore, the zero-emission operation of the electric excavator enhances the safety and health conditions within the tunnel, mitigating workers' exposure to harmful emissions and contributing to a healthier, more conducive working environment.
In summation, the electric excavator, despite presenting initial adaptation and investment challenges, aligns impeccably with sustainability, long-term economic viability, and enhanced health and safety conditions, thereby substantiating its potential as a formidable alternative to traditional diesel-powered excavators in tunnel construction projects amidst the global pivot towards sustainable practices.

Loader
Table 5 unfolds a comprehensive comparison between the electric loader (856E-MAX) and its diesel-powered equivalent (856H-MAX), each embodying distinct operational and economic characteristics that warrant a thorough exploration within the context of tunnel construction.www.nature.com/scientificreports/

Equipment parameters
The electric loader, with a maximum mechanical output power of 180 kW, slightly outperforms the diesel-powered loader, which delivers 168 kW, thereby ensuring a potent power delivery without compromising on intrinsic loading capabilities.However, it's crucial to note that the electric loader exhibits smaller maximum breakout and tractive forces compared to its diesel counterpart, potentially influencing its performance in certain operational contexts.Additionally, the electric loader, extending to 8,980 mm, surpasses its diesel counterpart by 307 mm, potentially introducing navigational complexities within the restricted confines of tunnel environments, thereby necessitating strategic operational planning to safeguard both efficiency and safety.Moreover, the endurance time of the electric loader, approximately one-third of the diesel model, demands frequent and strategically planned charging sessions to mitigate potential workflow disruptions.

Economic considerations
While the electric loader demands a notably higher initial investment, approximately 1.51 times that of the diesel variant, its working energy consumption cost is less than 40%, heralding potential long-term operational savings.Despite the initial financial outlay, the electric loader, over an extended period of use, emerges as a more economically prudent option, with cost amortization approximately 20% lower than the diesel power loader, thereby presenting a compelling economic narrative for its adoption.

In-depth analysis
The electric loader, despite its frequent charging requisites, operates with zero emissions, aligning seamlessly with global sustainability initiatives and potentially offering long-term economic and environmental dividends, especially in protracted projects.The frequent charging requirements necessitate astute strategic planning to seamlessly integrate charging sessions into the operational workflow, thereby minimizing disruptions and adhering to project timelines.Furthermore, the zero-emission operation of the electric loader enhances the safety and health conditions within the tunnel, mitigating workers' exposure to harmful emissions and contributing to a healthier, more conducive working environment.
In summation, the electric loader, despite presenting initial adaptation and investment challenges, aligns impeccably with sustainability, long-term economic viability, and enhanced health and safety conditions, thereby substantiating its potential as a formidable alternative to traditional diesel-powered loaders in tunnel construction projects amidst the global pivot towards sustainable practices.

Dump truck
Table 6 provides a detailed comparison between the electric dump truck (SYM3251ZZX3BEV319) and its dieselpowered counterpart (SYM3257ZZX1E), each embodying distinct operational and economic characteristics that warrant a thorough exploration within the context of tunnel construction.

Equipment parameters
Power Dynamics: The electric dump truck, with a maximum mechanical output power of 400 kW, surpasses the 360 kW offered by the diesel-powered dump truck, ensuring a robust power delivery while navigating through the tunnel environments.
Weight and Load Capacity: The electric dump truck, with a curb weight of 16.80 t, is notably heavier than its diesel counterpart, which weighs 12.43 t.This additional weight, attributed to the batteries and other components, reduces the load capacity of the electric dump truck by approximately 4 tons (or about 2 cubic meters) of tunnel dregs per trip under the maximum allowable total mass constraint.Consequently, to achieve equivalent workload, the number of electric dump trucks needs to be augmented by 25%.

Economic considerations
Initial Investment and Operational Costs: The electric dump truck demands a significantly higher initial investment, approximately 2.5 times that of the diesel variant, especially considering the need to increase the number of vehicles to achieve the same workload.Despite the electric dump truck presenting lower working energy consumption costs, the elevated initial investment and increased vehicle quantity result in a total cost amortization that is higher than the diesel power truck.

In-depth analysis
Environmental and Operational Efficiency: The electric dump truck, while operating with zero emissions and aligning with global sustainability initiatives, demands strategic operational planning to ensure that the reduced load capacity and increased vehicle requirements do not adversely impact the project timelines and workflow.
Strategic Planning: The reduced load capacity of the electric dump truck necessitates astute strategic planning to seamlessly integrate the increased vehicle requirements into the operational workflow, thereby minimizing disruptions and adhering to project timelines.
Long-term Economic Viability: The higher initial investment and operational complexities of the electric dump truck, when considered in the context of long-term projects, can potentially offset the initial investment, presenting a compelling case for its adoption in tunnel construction projects, especially considering the global shift towards sustainable practices.
In conclusion, the electric dump truck, while presenting initial challenges in terms of adaptation, investment, and operational planning, aligns impeccably with sustainability and presents a potential alternative to traditional diesel-powered dump trucks in tunnel construction projects amidst the global pivot towards sustainable www.nature.com/scientificreports/practices.However, its adoption necessitates meticulous planning and strategic considerations to ensure that the operational and economic implications are navigated effectively to harness its potential benefits.In summary, the exploration and analysis of electric equipment in the context of tunnel construction, especially within the challenging environments of plateau tunnels, reveal a nuanced tapestry of economic, environmental, and health-related considerations.The preceding sections, 4.1 through 4.4, have meticulously dissected the comparative attributes of electric and diesel-powered equipment, shedding light on their respective advantages and limitations in both operational and economic spectrums.
While the initial financial outlay for electric equipment is notably higher, attributed to the elevated equipment input costs and the financial commitment to energy replenishment infrastructures, it is imperative to recognize the long-term economic and non-economic benefits that unfold.The diminished working energy consumption costs and the significant carbon reduction impact of electric equipment underscore a commitment to sustainability and environmental stewardship, which is becoming increasingly pivotal in contemporary construction practices.
Moreover, the deployment of electric equipment heralds a marked improvement in the tunnel's air quality by mitigating exhaust emissions from fuel equipment.This not only alleviates the operational necessity and associated costs of tunnel ventilation but also crafts a healthier and safer working environment for construction personnel.The safeguarding of worker health, while not directly quantifiable in a financial matrix, is of paramount importance and presents an ethical and regulatory consideration that is integral to sustainable construction practices.
The trials involving electric muck transfer equipment, as detailed in this chapter, have not only substantiated an enhancement in the working environment and operational efficiencies within the plateau tunnel construction but have also demonstrated a tangible alignment with energy-saving and emission reduction objectives.Thus, while the economic investment in electric equipment is palpable, the amalgamation of environmental, health, and potential long-term operational benefits presents a compelling narrative for its adoption.This exploration, therefore, transcends its immediate context, offering valuable insights and reference points for future projects that seek to navigate the intricate balance between economic viability, environmental sustainability, and occupational health in tunnel construction within challenging terrains.

Research summary and limitations
The exploration into the application of electric equipment in plateau railway tunnel projects has unveiled a myriad of insights and potential pathways towards more sustainable, efficient, and environmentally responsible www.nature.com/scientificreports/construction practices.The research underscored the pivotal role of electric equipment in mitigating the multifaceted challenges posed by conventional fuel-powered machinery, particularly in the context of plateau environments characterized by reduced oxygen levels, extreme temperatures, and sensitive ecological conditions.Through a detailed examination of various policies, technological advancements, and practical applications, the research illuminated the potential of electric equipment to not only align with China's 'Dual Carbon' targets but also to navigate through the operational, environmental, and socio-economic challenges inherent in plateau railway tunnel construction.The adoption of electric equipment, particularly in muck transfer operations, was identified as a crucial strategy to reduce pollution, enhance worker safety and health, and improve operational efficiency amidst the challenging plateau conditions.
The implications of this research extend across multiple dimensions.For the research community, this study contributes to the burgeoning field of sustainable construction practices by providing empirical evidence on the efficacy of electric equipment in challenging environments.It lays the groundwork for further exploration into alternative energy solutions within the construction industry.For practice, the findings offer actionable insights for construction project managers and policymakers looking to reduce environmental impact and enhance efficiency in plateau railway tunnel projects.The adoption of electric muck transfer equipment, as demonstrated in our study, provides a tangible pathway towards achieving China's 'Dual Carbon' goals within the construction sector.For society, this research underscores the potential for significant environmental benefits, including reduced greenhouse gas emissions and lessened ecological disturbance, contributing to a more sustainable future.
While the research provides a comprehensive overview and analysis of the current situation, several limitations must be acknowledged:

Technological maturity：
The research is constrained by the current technological maturity and availability of electric construction machinery and equipment.The rapidly evolving nature of technology may introduce new solutions and challenges that are not addressed in the present study.

Data availability
The availability and accessibility of data, particularly pertaining to the real-world application, performance, and challenges of electric equipment in various tunneling projects, are limited.This restricts the depth and breadth of the analysis and findings.
Diverse Working Conditions: The research primarily focuses on the application of electric equipment in plateau railway tunnel projects, which may not fully encapsulate the diverse range of working conditions and challenges encountered in different geographical and environmental contexts.
Economic and Policy Dynamics: The economic and policy dynamics are subject to change, influenced by various factors like technological advancements, market conditions, and governmental policies, which might impact the feasibility and applicability of the findings in future contexts.
The aforementioned limitations necessitate a cautious and adaptive approach to applying the findings and recommendations of the research in practical scenarios.Future research and applications should consider the evolving technological landscape, emerging data, and changing economic and policy dynamics to ensure the relevance and efficacy of strategies and solutions in real-world contexts.
In light of these limitations, the findings and recommendations of the research serve as a foundational framework, providing valuable insights and directions for further exploration, development, and application of electric equipment in plateau railway tunnel projects.The continuous evolution of technologies, methodologies, and policies will invariably introduce new opportunities and challenges, warranting ongoing research and dialogue among stakeholders to navigate towards more sustainable, efficient, and responsible construction practices.

Policy recommendations and practical guidelines
Navigating through the complexities of adopting electric equipment in plateau railway tunnel projects necessitates a robust framework of policy recommendations and practical guidelines, wherein governmental support emerges as a linchpin, providing financial and infrastructural backing through policies, incentive programs, and a stringent regulatory framework that champions the use of environmentally congenial technologies in construction ventures, particularly within the ecologically delicate plateaus.In addition to the immediate operational and environmental benefits, the implementation of these policy recommendations and practical guidelines has profound implications for research, practice, and society.By fostering an ecosystem that encourages the use of electric equipment, we not only advance the research agenda in sustainable construction practices but also set a precedent for industry standards that prioritize environmental stewardship and worker safety.These guidelines serve as a model for other sectors, demonstrating the tangible benefits of integrating sustainable technologies into practical applications.On a societal level, these practices contribute to the realization of a greener, more sustainable future, aligning construction practices with global sustainability goals and enhancing public health through reduced emissions and pollution.The meticulous formulation and rigorous enforcement of standards for electric equipment become imperative, ensuring a steadfast adherence to safety, reliability, and efficiency across a spectrum of operational contexts, while on a practical note, the crafting of a phased strategy for the adoption of electric equipment, which prioritizes the foundational establishment of charging and battery-swap infrastructure, coupled with the implementation of comprehensive training programs for operators and maintenance personnel, becomes crucial to seamlessly navigate the operational and logistical challenges intertwined with the integration of novel technologies into extant workflows.Concurrently, the establishment of risk management protocols, designed to adeptly address potential challenges and disruptions related to the utilization of electric equipment in tunnel construction, acts as a safeguard, fortifying against operational and financial adversities.

Future research directions
Envisioning the future research directions in the domain of electric equipment utilization in plateau railway tunnel projects encompasses a multifaceted exploration into technological advancements, operational efficacy, socio-economic implications, and interdisciplinary research, with a pronounced focus on enhancing battery technology, delving into research that seeks to elevate energy density, expedite charging capabilities, and augment longevity, while also exploring the integration of automation and AI technologies to enhance efficiency and safety in tunnel construction activities.Beyond technological advancements, future research must emphasize the socio-economic and environmental impacts of electric equipment adoption.This includes studying the effects on worker health, community well-being, and contributing to sustainable development goals.Interdisciplinary research that bridges technology with policy analysis, social sciences, and environmental studies will be crucial for understanding the full spectrum of impacts and opportunities presented by electric equipment in construction.Investigative pursuits into innovative materials and technologies that can bolster the durability and performance of electric equipment, especially within the harsh environments of plateaus, emerge as a pivotal research avenue, while operational dynamics, environmental impact studies, and health and safety investigations will pave the way for data-driven insights and guidelines that optimize and safeguard tunnel construction practices.Furthermore, comprehensive economic analyses, social impact explorations, and investigations into the supply chain implications will illuminate the broader socio-economic ramifications and strategic considerations related to the adoption of electric equipment, and fostering intersectoral collaboration, engaging in international research collaborations, and exploring the broader sustainability implications of adopting electric equipment will ensure that practices are globally informed, technologically advanced, and holistically sustainable.

Figure 2 .
Figure 2. Layout of charging piles in the secondary lining area.

Figure 3 .
Figure 3.The first intelligent electrical change system for electric heavy truck in China.

Table 1 .
Summary of China's recent policies and regulations.
The Government will upgrade the level of green travel equipment, promote the large-scale application of new energy vehicles, accelerate the construction of charging infrastructure, and carry out "endurance projects" of green travel.Vigorously cultivate a green travel culture, improve public participation mechanisms, and build a green travel service system that is reasonably laid out, ecologically friendly, clean and low-carbon, intensive and efficient

Table 2 .
30anges of main performance parameters of diesel engine with altitude30.

Table 4 .
Comparison between electric excavator and diesel power products of the same class.

Table 5 .
Comparison between electric loader and diesel power products of the same class.

Table 6 .
Comparison between electric dump truck and diesel power products of the same class.