Low Emission Valve Packing, Carbon Core, PTFE Sleeve, 30 MPa

Storage Performance Deficiencies of Traditional Valves

Traditional valves using ordinary graphite packing face dual storage risks.

1. Physical Adsorption Leading to Operational Failure

During long-term static storage, graphite molecules adhere to the valve stem surface due to van der Waals forces, forming a rigid adsorption layer. This increases the valve opening torque by 2-3 times compared to the initial value. In extreme cases, it may cause the actuator to overload and fail.

2. Chemical Corrosion Leading to Seal Degradation

Ordinary graphite packing typically has a sulfur content of ≥1200 ppm (by mass). In storage environments with humidity ≥60%, sulfur reacts with the metal valve stem through electrochemical corrosion, forming a FeS corrosion layer. This enlarges the seal interface gap, causing the leakage rate to increase exponentially over time, with an average annual leakage increase of 30%-50%.

Storage Performance Advantages of Low Emission Valves

Low Emission Valves achieve a breakthrough in storage stability through the following means:

1. Upgraded Material System

Sealing Packing: High-purity sulfur-free graphite (sulfur content ≤0.01%) with ≥99.5% purity is used. The interlayer bonding is enhanced through nano-scale flake orientation technology, blocking the migration path of sulfur elements.

Mid-flange Gasket: Modified flexible graphite composite material with 15%-20% nickel-based alloy reinforcement is used to form a corrosion-resistant skeletal structure.

2. Performance Verification Data

Traditional Valves: Opening torque increases from 80 N•m to 220 N•m, and leakage rate rises from 500 ppm to 2800 ppm.

Low Emission Valves: Opening torque fluctuation is ≤±5%, and leakage rate remains below 20 ppm, fully meeting the stringent long-term storage performance requirements of API 624.

Basic Concept

Low Emission Valves refer to valves that, through special design and manufacturing processes of the stem packing and mid-seat gasket, control the leakage of media (gases, liquids) to extremely low levels. They are primarily used in industrial scenarios with high safety and environmental protection requirements. The core objective is to reduce or prevent the leakage of harmful media (such as volatile organic compounds (VOCs), toxic gases, flammable and explosive substances, etc.) into the external environment. Therefore, low emission valves offer multiple advantages in terms of energy conservation, emission reduction, reduced safety risks, and environmental pollution.

Key Technical Standards and Leakage Grades

The performance of Low Emission Valves is quantified by their leakage rate, and different industries follow different standards. Common standards include:

1. International Standards

ISO 15848-1: This standard classifies valve leakage grades into four levels: A (the highest requirement), B, C, and D. Grade A requires a leakage rate of ≤100 ppm (by volume).

API 624 (American Petroleum Institute): This standard, applicable to the refining and chemical industries, specifies a leakage rate of ≤100 ppm (for gases) under specific pressures.

EPA Standard (U.S. Environmental Protection Agency): This standard, targeting VOC emissions, requires a leakage rate of ≤500 ppm.

2. Chinese Standards

GB/T 42223-2022: This standard, which references international standards, regulates the design, manufacturing, and testing of Low Emission Valves.

Taking the petroleum refining industry as an example, if a conventional valve has a daily average leakage rate of 500 standard cubic meters (calculated based on the volume of gas under standard conditions), for a large refinery with 100,000 valves, the annual media emission loss can be quantified in the following dimensions.

1. Direct Material Loss

Annual leakage volume = 100,000 valves × 500 Nm³/valve•day × 365 days = 1.825 billion standard cubic meters of gas. If the unit price of natural gas is 3 yuan/Nm³, the annual direct economic loss reaches 5.475 billion yuan (without considering the cost of media recovery).

2. Increased Operation and Maintenance Costs

High leakage rates lead to a 3-5 times increase in on-site inspection frequency, with an additional annual maintenance cost of 2,000-3,000 yuan per valve, resulting in an extra 200 million - 300 million yuan in annual O&M costs for the entire plant; emergency shutdowns and repairs caused by sudden leaks can result in average losses of millions of yuan per incident.

3. Compliance Risk Costs

Leakages exceeding environmental emission standards (such as the volatile organic compound leakage limits specified in China's "Pollutant Emission Standards for the Petroleum Chemical Industry") may face:

Single administrative penalty: 100,000 - 1 million yuan

Production suspension and rectification: Daily value loss can reach tens of millions of yuan

Brand reputation loss: Leading to downstream customer loss or restricted financing

4. Release of Hidden Value

Using low emission valves (leakage rate ≤0.1 Nm³/valve•day) can achieve:

Annual emission reduction of over 1.8 billion cubic meters, meeting the carbon trading market quota requirements and creating additional revenue

More than 40% improvement in operation and maintenance efficiency, with a 5%-8% increase in overall equipment utilization rate

Avoidance of the risk of downgraded environmental credit rating, ensuring project approval and expansion qualifications

Conclusion: Low Emission Valves, through a three-dimensional value system of "material conservation control, operation and maintenance efficiency optimization, compliance risk isolation", can not only directly reduce losses of hundreds of millions of yuan but also build a sustainable development capability that meets ESG (environmental, social, and corporate governance) requirements. Especially under the "dual carbon" goals, they have become a core cost control tool for industries with high leakage risks.