How Servo Press Machines Help You Achieve Green Manufacturing and Cost Efficiency?

Amid persistently rising global energy prices and increasing pressure to reduce carbon emissions, manufacturing companies are facing unprecedented dual challenges of cost control and environmental compliance. As critical equipment in industrial production, the energy consumption of press machines directly impacts operational costs and environmental footprints. Traditional press machines, especially hydraulic ones, often suffer from high energy consumption and low efficiency due to their working principles and structural characteristics, becoming a bottleneck for manufacturers in reducing costs and achieving green transformation.

Servo press machines, as modern pressing equipment incorporating advanced servo control technology, have emerged as an ideal choice for manufacturers seeking green manufacturing and cost efficiency, thanks to their exceptional energy-saving performance and precise control capabilities. This article will delve into the energy consumption issues of traditional press machines, elaborate on the energy-saving mechanisms of servo press machines, and demonstrate through real-world case studies and data how servo press machines can help companies lower energy costs while improving production efficiency and product quality, achieving a win-win scenario for both economic and environmental benefits.

一、The Energy Consumption Dilemma of Traditional Press Machines: Problem Analysis

1. Energy Consumption Characteristics of Traditional Hydraulic Press Machines

Traditional hydraulic press machines are among the most widely used pressing equipment in manufacturing, and their energy consumption issues are primarily reflected in the following aspects:

• Continuous Operation of the Power System: Traditional hydraulic press machines require hydraulic pumps to run continuously to maintain system pressure. Even during non-working cycles (e.g., waiting for material loading or mold changes), the hydraulic pump must remain operational, leading to significant energy waste. Statistics show that in typical stamping production, the actual working time of a hydraulic system usually accounts for only 30%-40% of the total operating time, while the remaining time is spent idling or in standby mode—yet still consuming energy.
• Inefficient Energy Conversion Chain: The energy conversion process in hydraulic systems is complex, involving transitions from electrical energy to mechanical energy (motor driving the hydraulic pump), then to hydraulic energy (oil pressure), and finally back to mechanical energy (piston movement). Each step incurs energy losses. The typical energy conversion efficiency of a hydraulic system is only 50%-60%, meaning nearly half of the input energy is wasted.
• System Leakage and Heat Loss: Hydraulic systems inevitably experience internal and external leakage, which not only causes pressure loss but also results in energy waste. Additionally, the heat generated during the operation of hydraulic systems dissipates into the environment through components like the oil tank and pipelines, representing yet another form of energy waste. In large hydraulic press machines, this heat loss can account for 15%-20% of total energy consumption.
• Crude Pressure Control Methods: Traditional hydraulic systems often rely on simple pressure control mechanisms like relief valves. When the required pressure is lower than the system’s maximum pressure, the excess energy is wasted as heat through the relief valve. This control method, while straightforward, is highly inefficient, especially in applications requiring precise pressure control.
• Limitations of Fixed-Displacement Pumps: Many traditional hydraulic press machines use fixed-displacement pumps, which cannot adjust flow rates according to actual demand, leading to even lower energy utilization under low-load conditions.

2. Energy Efficiency Issues of Traditional Mechanical Press Machines

Compared to hydraulic press machines, traditional mechanical press machines (such as crank presses, toggle presses, etc.) exhibit higher energy efficiency in certain aspects, but they still face significant energy consumption problems:

• Flywheel Energy Storage and Loss: Mechanical press machines rely on flywheels to store energy. During non-operating phases, the motor must continuously replenish the energy lost to friction in the flywheel, resulting in persistent energy consumption.
• Fixed Motion Patterns: The motion patterns of traditional mechanical press machines are determined by their mechanical structures, making it impossible to optimize the motion process according to specific process requirements. This often leads to inefficient energy utilization in many applications.
• Wasted Braking Energy: At the end of each working cycle, residual kinetic energy is typically converted into heat and dissipated by the braking system, rather than being recovered and reused.
• High Energy Consumption of Auxiliary Systems: The auxiliary systems of traditional mechanical press machines, such as lubrication and cooling systems, are often simply designed with low energy efficiency, becoming hidden sources of energy consumption.

3. Multiple Challenges Caused by Excessive Energy Consumption

The high energy consumption of traditional press machines poses multiple challenges for manufacturing enterprises:

• Operational Cost Pressure: Energy costs represent a major operational expense for manufacturers. Against the backdrop of rising energy prices, high-energy-consuming equipment directly increases production costs, undermining a company’s price competitiveness.
• Environmental Compliance Risks: As global carbon reduction policies become stricter, high-energy-consuming equipment faces growing compliance pressures. The implementation of mechanisms like the EU Carbon Border Adjustment Mechanism (CBAM) means that a company’s carbon emissions directly impact product market access and cost competitiveness.
• Green Manufacturing Transition Pressure: With the growing emphasis on sustainable development, downstream customers (particularly international brands) are imposing higher environmental standards on supply chains. Energy-inefficient production equipment has become a barrier to corporate green transformation.
• Capacity Expansion Constraints: In some regions, energy supply and consumption quotas have become key factors in approving new projects. High-energy-consuming equipment limits companies’ capacity expansion plans.
• Production Efficiency Bottlenecks: Energy consumption issues often correlate with productivity problems. High energy consumption typically indicates suboptimal overall equipment efficiency, creating bottlenecks in productivity improvement.

二、Energy-Saving Mechanisms of Servo Press Machines: Technical Analysis

Servo press machines fundamentally address the energy consumption issues of traditional presses by integrating advanced servo drive technology and intelligent control systems, achieving remarkable energy-saving effects. Their core energy-saving mechanisms include:

1. On-Demand Energy Supply Principle

The most fundamental energy-saving mechanism of servo press machines is the “on-demand energy supply” principle, which provides energy only when and as much as needed:

• Zero Energy Consumption in Non-Working States: Unlike traditional hydraulic presses, servo press machines can completely halt energy input during non-working states (e.g., waiting for material loading or mold changes), achieving near-zero standby energy consumption. This feature is particularly valuable in scenarios with slow production cycles or frequent downtime.
• Precisely Matched Energy Output: The servo system can precisely control the energy required for each work cycle, avoiding excessive energy supply. For example, under light-load conditions, the system automatically reduces energy output instead of maintaining maximum power as traditional systems do.
• Intelligent Standby Management: Advanced servo press machines are equipped with intelligent standby management systems that can automatically switch between different energy consumption modes—such as full-power mode, low-power mode, and standby mode—based on production status, minimizing energy waste during non-production periods.

2. High-Efficiency Direct Drive Technology

Servo press machines employ direct drive technology that significantly improves energy conversion efficiency:

• Simplified Energy Conversion Chain: Fully electric servo presses directly convert electrical energy into mechanical energy, eliminating multiple energy conversion stages present in hydraulic systems. This achieves energy conversion efficiency of 85%-90%, far surpassing the 50%-60% efficiency of traditional hydraulic systems.
• High-Efficiency Servo Motors: Modern servo motors utilize high-performance permanent magnet materials and optimized electromagnetic design, delivering exceptional energy efficiency that typically meets or exceeds IE4 and even IE5 efficiency standards.
• Precision Transmission Systems: The use of high-efficiency mechanical transmission components (such as precision ball screws and planetary reducers) further minimizes energy losses in mechanical transmission.
• Reduced Heat Loss: The high energy conversion efficiency substantially decreases heat generation, reducing energy dissipation in the form of heat.

3. Innovative Energy Recovery Technology

A key technological highlight of servo press machines is their energy recovery system, which repurposes traditionally wasted energy:

• Braking Energy Recovery: During deceleration and downward movement, the servo motor operates in generator mode, converting mechanical energy back into electrical energy. This energy is either fed back to the grid via a regeneration unit or stored in energy storage devices. In certain applications, up to 20%-30% of total energy consumption can be recovered this way.
• Potential Energy Recovery: The system can harness the potential energy of the slide and dies during gravity-driven descent, further enhancing energy utilization efficiency.
• Energy Storage Technology: Some advanced servo press machines are equipped with energy storage devices like supercapacitors or flywheels. These temporarily store recovered energy for reuse in the next work cycle, smoothing peak energy demands and improving overall energy efficiency.

4. Intelligent Control and Optimization Algorithms

The intelligent control system of servo press machines further optimizes energy usage through advanced algorithms:

• Motion Trajectory Optimization: The system automatically calculates the optimal motion trajectory based on process requirements, minimizing energy consumption while meeting technical specifications.
• Multi-axis Coordination Control: For multi-axis servo presses, the intelligent control system coordinates movement across all axes to prevent unnecessary energy consumption. For example, braking energy from one axis can be utilized for another axis’s acceleration.
• Adaptive Control Strategy: The system dynamically adjusts control parameters according to actual load conditions to maintain optimal energy efficiency.
• Predictive Control: By forecasting work cycles, the system proactively plans energy allocation to prevent waste and peak demand spikes.

5. Whole-system Energy Efficiency Design

Beyond the core drive system, servo press machines incorporate comprehensive energy-efficient design principles:

• High-efficiency Auxiliary Systems: Cooling and lubrication systems employ variable-frequency control and intelligent management to adjust operation based on real-time needs, eliminating redundant energy use.
• Low-friction Design: Mechanical structures utilize low-friction designs and high-quality bearings to reduce mechanical friction losses.
• Thermal Management Optimization: Enhanced thermal design minimizes heat generation while improving dissipation efficiency, preventing performance degradation due to temperature rise.
• Lightweight Construction: Optimized lightweight structural designs maintain rigidity and strength while reducing moving part mass, thereby lowering energy demands during acceleration/deceleration phases.

三、Cost-Saving and Efficiency Benefits of Servo Press Machines: Data and Case Studies

The energy-saving features of servo press machines translate directly into significant economic benefits and productivity improvements, as demonstrated by the following specific data and case examples:

1. Quantitative Analysis of Energy Cost Savings

Real-world application data shows substantial energy savings achieved by servo press machines compared to traditional presses:

• Overall Energy Consumption Reduction: Servo press machines reduce energy consumption by 30%-70% compared to traditional hydraulic presses of the same tonnage, with the exact savings depending on application scenarios and work cycle characteristics.
• Near-Zero Standby Energy Consumption: In non-operating states, servo press machines can reduce energy consumption by over 95%, a particularly valuable feature for intermittent production or frequent mold-change scenarios.
• Reduced Peak Power Demand: The intelligent control system of servo press machines smooths power demand curves, reducing peak power requirements by 20%-40%. This directly lowers electricity infrastructure costs and demand charges.

Energy Cost Savings Case Studies:

• An automotive parts manufacturer replaced a 200-ton traditional hydraulic press with a servo press of the same capacity, reducing annual electricity costs from approximately ¥120,000 to ¥40,000—a 67% savings.
• A home appliance manufacturer’s stamping workshop reported annual savings of about ¥80,000 per machine after switching to servo presses, recouping the upgrade investment through electricity savings alone within 5 years.
• A precision electronics component manufacturer replaced pneumatic pressing equipment with small servo presses, achieving an 80% reduction in energy costs and annual savings of approximately ¥150,000 in electricity and compressed air costs.

2. Productivity Improvement and Indirect Cost Reduction

Servo press machines not only directly reduce energy costs but also enhance economic benefits by improving production efficiency and lowering indirect costs:

• Increased Production Cycle Speed: By optimizing motion curves and reducing unnecessary idle time, servo press machines typically improve production efficiency by 15%-40% in practical applications.
• Reduced Mold Changeover Time: The simplified parameter adjustment of servo presses shortens mold changeover time by 30%-50%, significantly improving equipment utilization.
• Lower Defect Rates: Precise force and position control ensure more stable product quality, typically reducing defect rates by over 50%, thereby saving material and rework costs.
• Extended Mold Life: Optimized motion curves and accurate force control minimize impact and wear on molds, extending mold lifespan by 30%-100% and substantially reducing mold costs and replacement frequency.
• Reduced Maintenance Costs: With simpler structures and fewer wear-prone components, servo systems require significantly less maintenance, cutting maintenance costs by 40%-60% compared to traditional hydraulic systems.
• Comprehensive Benefit Case Studies:
  • An automotive stamping parts manufacturer achieved 50% energy cost reduction, along with 25% productivity improvement, 40% longer mold life, and 60% lower defect rates, generating over ¥1 million in annual comprehensive economic benefits after adopting servo presses.
  • An electronic connector manufacturer improved product yield from 96% to 99.5% after switching to precision servo presses, achieving a payback period of just 1.5 years when combined with energy savings and efficiency gains.

3. Carbon Reduction Benefits and Green Manufacturing Value

The energy-saving features of servo press machines directly translate into carbon reduction benefits, supporting enterprises in achieving green manufacturing:

• Significant Carbon Emission Reduction: Lower energy consumption directly reduces carbon emissions. Based on China’s grid emission factor, saving 10,000 kWh of electricity can reduce carbon emissions by approximately 6-8 tons.

• Reduced Environmental Compliance Costs: In regions with carbon trading or carbon tax policies, lower carbon emissions directly decrease costs associated with carbon quota purchases or tax payments.
• Advantages in Green Supply Chain Certification: Low-carbon production equipment helps companies obtain various green manufacturing and supply chain certifications, enhancing competitiveness in international markets.
• Green Manufacturing Case Studies:
  • An export-oriented manufacturer reduced annual carbon emissions by approximately 2,000 tons after fully transitioning to servo press machines, successfully obtaining green supplier certification from EU clients and increasing order volume by 30%.
  • A newly established press workshop exclusively using servo press machines not only met stringent local energy consumption requirements but also qualified for government green manufacturing subsidies, reducing initial investment costs.

4. Investment Return Analysis and Economic Evaluation

Although servo press machines typically require higher initial investment than traditional presses, their comprehensive benefits deliver significantly superior economic performance:

• Typical Payback Period: Depending on application scenarios and usage intensity, the payback period for servo press machines generally ranges from 2-4 years, with high-intensity production scenarios potentially achieving 1-2 years.
• Lifecycle Cost Advantage: When considering total cost of ownership (TCO) over the equipment’s lifecycle (typically 15-20 years), servo press machines demonstrate 20%-40% lower costs compared to traditional presses. This stems from integrated benefits including energy savings, reduced maintenance, and productivity gains.
• Investment Decision Considerations:
  • Energy Price Trends: Rising energy prices will further amplify the economic advantages of servo press machines.
  • Carbon Policy Impact: Stricter carbon trading schemes and carbon taxes increase hidden costs for high-emission equipment.
  • Green Finance Support: Many regions offer preferential loans, subsidies, or tax incentives for energy-efficient equipment, mitigating initial investment burdens.
  • Market Competition: Green and low-carbon production has become a critical competitive differentiator affecting long-term market positioning.

四、Energy-Saving Technology Innovation and Implementation of Shuntec Servo Press Machines

As a professional manufacturer in the servo press machine field, Shuntec has conducted in-depth research and innovation in energy-saving technologies, developing a series of servo press products with remarkable energy-saving effects.

1. Full Range of Energy-Efficient Servo Press Machine Products

Shuntec offers a comprehensive lineup of energy-saving servo press machines, covering small to large tonnage applications:

• SE Series Fully Electric Servo Press Machines: With a tonnage range of 5-300 tons, these machines adopt fully electric servo drive technology, reducing energy consumption by 60%-70% compared to traditional hydraulic presses. They are ideal for precision forming, assembly, and similar processes.

• SH Series Electro-Hydraulic Hybrid Servo Press Machines: Featuring a tonnage range of 100-2000 tons, these machines combine the advantages of servo control and hydraulic transmission, achieving 40%-50% energy savings compared to conventional hydraulic presses. They are suitable for high-tonnage forming, forging, and other demanding applications.
• SM Series Multi-Station Servo Press Machines: Designed for continuous multi-process production, these machines optimize energy distribution across workstations, delivering over 50% higher energy efficiency compared to traditional multi-station presses.
• SP Series Precision Servo Press Machines: Developed for precision manufacturing in industries like electronics and medical devices, these ultra-precision servo presses maintain micron-level accuracy while reducing energy consumption by more than 70% compared to traditional precision pressing equipment.

2. Leading Energy-Saving Technology Features

Shuntec servo press machines incorporate multiple innovations and advantages in energy-saving technologies:

• High-Efficiency Servo Drive System: Utilizes IE5 ultra-high-efficiency servo motors and optimized drive control algorithms to maximize energy conversion efficiency.
• Advanced Energy Recovery Technology: Equipped with a next-generation energy recovery system boasting over 90% recovery efficiency, significantly improving energy utilization.
• Intelligent Energy Management System: The proprietary ShuntecEMS energy management system enables real-time monitoring and optimization of energy usage, automatically adjusting energy allocation strategies based on production demands.
• Multi-Stage Energy-Saving Modes: Offers various selectable energy-saving modes (e.g., Standard Mode, High-Efficiency Mode, Ultra-Energy-Saving Mode), allowing flexible adaptation to production requirements.
• Thermal Energy Recovery: Selected models feature a thermal energy recovery system that repurposes waste heat for facility heating or production-related hot water, further enhancing comprehensive energy utilization.
• Lightweight Design: Incorporates advanced structural optimization and material applications to reduce moving component mass while maintaining rigidity and strength, thereby lowering energy demands.

3. Intelligent Energy-Saving Control System

Shuntec servo press machines are equipped with advanced intelligent energy-saving control systems:

• ShuntecSmart Control Platform: A proprietary intelligent control platform integrating multiple energy-saving algorithms to automatically optimize motion curves and energy usage based on process requirements.
• Process Parameter Optimization: The system analyzes historical production data to recommend the most energy-efficient parameter combinations, enabling continuous energy efficiency improvements.
• Energy Consumption Monitoring & Analysis: Real-time monitoring and recording of energy consumption data, generating detailed energy analysis reports to identify optimization opportunities.
• Predictive Maintenance: Detects potential energy efficiency anomalies by monitoring changes in energy consumption patterns, enabling timely maintenance to sustain optimal efficiency.
• Remote Energy Efficiency Optimization Service: Provides remote energy efficiency diagnostics and optimization, where Shuntec experts analyze equipment energy data via remote connection to deliver customized energy-saving recommendations.

4. Success Case Studies

Shuntec servo press machines have numerous successful cases in helping customers achieve green manufacturing and cost-efficiency improvements:

• A German Automotive Parts Manufacturer: Replaced traditional hydraulic presses with Shuntec SH series electro-hydraulic hybrid servo presses, achieving 52% energy reduction and annual electricity cost savings of approximately €150,000. Additionally, production efficiency increased by 20%, and product qualification rate improved by 3 percentage points, delivering significant comprehensive benefits.
• A U.S. Home Appliance Manufacturer: Fully upgraded their stamping workshop with Shuntec SE series fully electric servo presses, reducing energy consumption by 65% and cutting annual carbon emissions by around 1,200 tons. This not only lowered production costs but also helped the company obtain ENERGY STAR® certification, enhancing brand reputation.
• A Japanese Precision Electronics Manufacturer: Adopted Shuntec SP series precision servo presses for micro-component assembly, achieving 80% lower energy consumption compared to previous pneumatic equipment. At the same time, assembly accuracy and consistency significantly improved, reducing defect rates from 3% to 0.2% with notable overall benefits.
• A Chinese Export-Oriented Manufacturer: After fully implementing Shuntec servo presses, the company not only reduced production costs but also passed carbon footprint certification, successfully entering high-end markets in Europe and America. Order volume increased by 40%, with significantly enhanced product premium pricing capability.

五、Implementation Pathway for Energy-Saving Transformation with Servo Press Machines

For enterprises considering servo press machines to achieve green manufacturing and cost-efficiency improvements, we recommend the following systematic implementation approach:

1. Energy Consumption Assessment and Savings Potential Analysis

Begin with a comprehensive evaluation of existing equipment and production lines:

• Baseline Energy Measurement: Use professional energy monitoring equipment to measure actual energy consumption of current presses under various operating conditions, establishing baseline energy data.
• Energy Distribution Analysis: Analyze energy distribution across different work phases (e.g., acceleration, operation, standby) to identify major energy-consuming segments.
• Savings Potential Evaluation: Based on baseline measurements and distribution analysis, assess potential energy savings and economic benefits considering servo press technical features.
• Carbon Impact Assessment: Calculate potential carbon reduction from energy savings, evaluating positive impacts on corporate carbon footprint and environmental compliance.

2. Equipment Selection and Customized Solutions

Based on energy assessment results, select the most suitable servo press solution:

• Process Requirement Analysis: Conduct detailed analysis of production process characteristics and requirements, including tonnage needs, precision demands, production cycle times, etc., to ensure selected equipment meets technical specifications.
• Energy Efficiency Target Setting: Establish clear energy efficiency improvement targets aligned with corporate cost control and environmental objectives as key selection criteria.
• Equipment Configuration Optimization: Choose appropriate servo press models and configurations (e.g., fully electric vs. electro-hydraulic hybrid, standard vs. ultra-high efficiency) based on specific application needs.
• Auxiliary System Planning: Incorporate energy-efficient designs for cooling, lubrication, and other auxiliary systems to maximize overall system efficiency.
• Automation Integration Considerations: For planned automation integration, evaluate production line-wide energy optimization to prevent localized improvements compromising overall efficiency.

3. Economic Analysis and Investment Decision

Conduct comprehensive economic evaluation prior to investment decisions:

• Initial Investment Assessment: Include direct costs such as equipment procurement, installation/commissioning, and personnel training.
• Operational Cost Savings Calculation: Quantify savings from reduced energy consumption, lower maintenance costs, and decreased defect rates.
• Productivity Enhancement Value: Assess economic benefits from increased production capacity and improved delivery capabilities.
• ROI Period Calculation: Compute payback period and internal rate of return (IRR) by integrating all cost/benefit factors to support decision-making.
• Financing & Incentive Policy Research: Investigate available green financing options, energy efficiency subsidies, and tax incentives to optimize investment plans.

4. Implementation and Optimization Strategies

After equipment introduction, adopt systematic implementation and optimization strategies to maximize energy-saving effects:

• Benchmark Testing & Acceptance: Conduct post-installation benchmark tests to verify whether actual energy consumption meets expected targets.
• Operator Training: Provide comprehensive training to operators on energy-saving features and proper operation methods to prevent efficiency losses due to improper handling.

• Process Parameter Optimization: Optimize parameter settings based on actual production needs to maximize energy efficiency while maintaining product quality.
• Continuous Monitoring & Improvement: Establish energy consumption monitoring and analysis mechanisms to regularly evaluate equipment performance and identify further optimization opportunities.
• Preventive Maintenance Plan: Develop scientific preventive maintenance schedules to ensure long-term optimal energy efficiency.

5. Plant-Wide Energy Efficiency Enhancement Plan

Integrate servo press energy-saving transformations into corporate-wide efficiency improvement plans:

• Phased Implementation Strategy: Develop staged equipment renewal plans based on current asset conditions and investment capacity, prioritizing replacement of highest-consumption or most frequently used equipment.
• Energy Management System Development: Establish ISO 50001-compliant energy management systems to systematically advance corporate energy efficiency.
• Green Manufacturing Certification Planning: Align energy-saving transformations with green manufacturing certifications and low-carbon product certifications to enhance environmental competitiveness.
• Employee Energy Awareness Cultivation: Conduct energy conservation training and awareness campaigns to foster corporate energy-saving culture.
• Continuous Technology Tracking & Updates: Monitor energy-saving technology developments and promptly adopt new methods for sustained efficiency gains.

六、Conclusion: The Win-Win Path of Green Manufacturing and Cost Efficiency

Against the backdrop of rising global energy prices and increasing carbon reduction pressures, manufacturing enterprises face unprecedented dual challenges of cost control and environmental compliance. The high energy consumption of traditional press machines has become a bottleneck for manufacturers seeking cost efficiency and green transformation. With their exceptional energy-saving characteristics and precise control capabilities, servo press machines offer manufacturers a win-win solution to achieve both green manufacturing and cost efficiency.

Through this analysis, we clearly demonstrate that servo press machines not only significantly reduce energy consumption (typically saving 30%-70% compared to conventional equipment) but also deliver comprehensive economic benefits through improved production efficiency, reduced defect rates, and extended mold life. Simultaneously, lower energy consumption directly translates to reduced carbon emissions, helping enterprises meet increasingly stringent environmental regulations while enhancing green competitiveness.

As a professional manufacturer in the servo press machine field, Shuntec has developed a series of highly energy-efficient products through continuous technological innovation and practical experience. We provide end-to-end services—from energy assessment and customized solutions to implementation optimization—helping numerous manufacturers successfully achieve dual objectives of green manufacturing and cost efficiency.

At this critical juncture of manufacturing transformation and upgrading, choosing energy-saving servo press machines represents not only a smart response to current energy and environmental challenges but also a strategic investment in long-term competitiveness. We believe that with advancing energy-saving technologies and growing adoption of green manufacturing principles, servo press machines will play an increasingly vital role in the industry’s green transition, leading the way toward a more sustainable future.

If your enterprise faces challenges like excessive energy consumption, cost pressures, or environmental compliance risks, contact Shuntec’s professional team today. We will provide tailored servo press energy-saving solutions to help your business achieve the dual goals of green manufacturing and cost efficiency.