Ar Buffer Tank – Efficient Storage Solution for Your Products
Product advantage
When it comes to industrial processes, efficiency and productivity are crucial. The AR surge tank is a critical component that plays an important role in achieving optimal performance. This article will explore the characteristics of the AR surge tank, highlighting its benefits and why it is a valuable addition to a variety of industrial systems.
An AR surge tank, also known as an accumulator tank, is a storage vessel used to hold pressurized gas (in this case, AR or argon). It is designed to maintain stable AR flow and pressure within the system to ensure continuous supply to various equipment and processes.
One of the main features of AR buffer tanks is the ability to store large amounts of AR. The capacity of a water tank may vary depending on the specific requirements of the system into which it is integrated. By having a sufficient number of ARs, processes can run smoothly without interruption, eliminating downtime and increasing overall efficiency.
Another important feature of the AR surge tank is its pressure regulation capability. The tank is equipped with a pressure relief valve to help maintain a consistent pressure range within the system. This feature prevents pressure spikes or drops that could damage equipment or disrupt the production process. It also ensures the AR is delivered at the correct pressure for optimal performance and consistent results.
The construction of the AR buffer tank is equally important. These tanks are usually made of high-quality materials such as stainless steel to ensure durability and corrosion resistance. Stainless steel storage tanks are known for their exceptional strength, allowing them to withstand high pressures and extreme temperature changes. This feature is critical in industrial environments where tanks are exposed to harsh conditions.
Additionally, AR surge tanks are equipped with various safety features. For example, they have pressure gauges and sensors to monitor the pressure levels of storage tanks in real time. These pressure gauges act as an early warning system, alerting operators to any pressure anomalies so that corrective measures can be taken promptly.
Additionally, AR surge tanks are designed to be easily integrated into existing systems. They can be customized to meet specific requirements, ensuring seamless compatibility across industrial settings. Proper tank placement in the system is critical as it ensures efficient distribution of AR to the equipment that needs it.
In summary, the properties of AR surge tanks make them valuable components in industrial processes. Its ability to store large amounts of AR, regulate pressure and maintain consistent performance ensures uninterrupted operations and increased productivity. Additionally, durability, safety features, and ease of integration further enhance its importance.
When considering the installation of an AR surge tank, it is important to consult an expert who can provide guidance on the specifications of the surge tank and its optimal location in the system. With the right storage tanks, industrial processes can run smoothly, increasing productivity and cost-effectiveness.
Product Features
Argon buffer tanks (commonly known as argon buffer tanks) are an important part of various industries. It is used to conserve and regulate the flow of argon gas, making it an important component in many applications. In this article, we will explore the different applications of Ar buffer tanks and discuss the benefits of their use.
Argon surge tanks are suitable for industries that rely heavily on argon and require a continuous supply. Manufacturing is one such industry. Argon gas is widely used in metal fabrication processes such as welding and cutting. Argon surge tanks ensure a continuous supply of argon, eliminating the risk of interruptions in these critical processes. With surge tanks in place, manufacturers can increase productivity by minimizing downtime and maintaining steady gas flow.
The pharmaceutical industry is another area where Ar buffer tanks play an important role. In pharmaceutical manufacturing, maintaining a sterile environment is crucial. Argon helps create an oxygen-free environment, preventing microbial growth and ensuring product purity. By using argon surge tanks, pharmaceutical companies can regulate the flow of argon gas into their manufacturing processes to maintain the desired level of sterility throughout the production process.
The electronics industry is another industry that benefits from the use of Ar buffer tanks. Argon is commonly used in the production of semiconductors and other electronic components. These precision parts require a controlled environment to prevent oxidation, which can adversely affect their performance. Argon buffer tanks help maintain a stable argon atmosphere, ensuring the quality and reliability of manufactured electronic components.
In addition to these specific industries, argon surge tanks also find use in laboratory settings. Research laboratories rely on argon gas to produce a variety of analytical instruments, such as gas chromatographs and mass spectrometers. These instruments require a steady flow of argon gas to operate accurately. Ar buffer tanks help ensure a steady supply of gas, allowing researchers to obtain reliable and reproducible results in their experiments.
Now that we have explored the applications of Ar surge tanks, let’s discuss the benefits they offer. One of the significant advantages of using a surge tank is the ability to continuously supply argon. This eliminates the need for frequent cylinder changes and minimizes the risk of disruption, increasing efficiency and productivity across industries.
In addition, argon surge tanks help regulate argon pressure, preventing sudden surges that can damage equipment or compromise the integrity of the process. By maintaining a stable pressure, surge tanks ensure steady gas flow, optimizing performance and reducing the likelihood of costly equipment failure.
Additionally, argon surge tanks provide greater control over argon gas usage. By monitoring gas levels in storage tanks, companies can accurately assess their consumption and optimize usage accordingly. This not only helps streamline operations and reduce costs, but also facilitates a more sustainable approach to resource management.
In summary, Ar buffer tanks have a wide range of applications and bring significant benefits to various industries. From manufacturing and pharmaceuticals to electronics and research laboratories, use argon surge tanks to ensure a constant supply of argon, regulate pressure and better control usage. With these advantages in mind, it's clear why Ar surge tanks are a valuable investment for businesses looking to increase productivity, enhance process stability and reduce operating costs.
Factory
Departure Site
Production site
Design parameters and technical requirements | ||||||||
serial number | project | container | ||||||
1 | Standards and specifications for design, manufacture, testing and inspection | 1. GB/T150.1~150.4-2011 “Pressure Vessels”. 2. TSG 21-2016 “Safety Technical Supervision Regulations for Stationary Pressure Vessels”. 3. NB/T47015-2011 “Welding Regulations for Pressure Vessels”. |
||||||
2 | design pressure MPa | 5.0 | ||||||
3 | work pressure | MPa | 4.0 | |||||
4 | set tempreture ℃ | 80 | ||||||
5 | Operating temperature ℃ | 20 | ||||||
6 | medium | Air/Non-toxic/Second Group | ||||||
7 | Main pressure component material | Steel plate grade and standard | Q345R GB/T713-2014 | |||||
recheck | / | |||||||
8 | Welding materials | submerged arc welding | H10Mn2+SJ101 | |||||
Gas metal arc welding, argon tungsten arc welding, electrode arc welding | ER50-6,J507 | |||||||
9 | Weld joint coefficient | 1.0 | ||||||
10 | Lossless detection |
Type A, B splice connector | NB/T47013.2-2015 | 100% X-ray, Class II, Detection Technology Class AB | ||||
NB/T47013.3-2015 | / | |||||||
A, B, C, D, E type welded joints | NB/T47013.4-2015 | 100% magnetic particle inspection, grade | ||||||
11 | Corrosion allowance mm | 1 | ||||||
12 | Calculate thickness mm | Cylinder: 17.81 Head: 17.69 | ||||||
13 | full volume m³ | 5 | ||||||
14 | Filling factor | / | ||||||
15 | heat treatment | / | ||||||
16 | Container categories | Class II | ||||||
17 | Seismic design code and grade | level 8 | ||||||
18 | Wind load design code and wind speed | Wind pressure 850Pa | ||||||
19 | test pressure | Hydrostatic test (water temperature not lower than 5°C) MPa | / | |||||
air pressure test MPa | 5.5 (Nitrogen) | |||||||
Air tightness test | MPa | / | ||||||
20 | Safety accessories and instruments | pressure gauge | Dial: 100mm Range: 0~10MPa | |||||
safety valve | set pressure:MPa | 4.4 | ||||||
nominal diameter | DN40 | |||||||
21 | surface cleaning | JB/T6896-2007 | ||||||
22 | Design service life | 20 years | ||||||
23 | Packaging and Shipping | According to the regulations of NB/T10558-2021 “Pressure Vessel Coating and Transport Packaging” | ||||||
“Note: 1. The equipment should be effectively grounded, and the grounding resistance should be ≤10Ω.2. This equipment is regularly inspected according to the requirements of TSG 21-2016 “Safety Technical Supervision Regulations for Stationary Pressure Vessels”. When the corrosion amount of the equipment reaches the specified value in the drawing ahead of time during the use of the equipment, it will be stopped immediately.3. The orientation of the nozzle is viewed in the direction of A. “ | ||||||||
Nozzle table | ||||||||
symbol | Nominal size | Connection size standard | Connecting surface type | purpose or name | ||||
A | DN80 | HG/T 20592-2009 WN80(B)-63 | RF | air intake | ||||
B | / | M20×1.5 | Butterfly pattern | Pressure gauge interface | ||||
( | DN80 | HG/T 20592-2009 WN80(B)-63 | RF | air outlet | ||||
D | DN40 | / | welding | Safety valve interface | ||||
E | DN25 | / | welding | Sewage Outlet | ||||
F | DN40 | HG/T 20592-2009 WN40(B)-63 | RF | thermometer mouth | ||||
M | DN450 | HG/T 20615-2009 S0450-300 | RF | manhole |