Are you tired of subpar pumps that can't keep up with your high-demand applications? Look no further! Shinhoo is proud to unveil our latest innovation, Mega S 80-8F, designed specifically for those who demand the best in performance, reliability, and efficiency.

 

Max Flow: 37m³/h 

 Say goodbye to sluggish circulation! Our pump boasts an impressive maximum flow rate that ensures your systems run smoothly, even under the heaviest loads.

 

No Leakage & High Efficiency

 With a leak-proof design and cutting-edge technology,  Mega S 80-8F delivers unparalleled efficiency, reducing energy consumption and saving you money.

 

Insulation Class: H

Safety first! Our pump meets the highest insulation standards, ensuring it's safe and reliable for both residential and commercial use.

 

Self-Lubrication & Self-Cooling - Maintenance-free and hassle-free!

Mega S 80-8F features self-lubricating and self-cooling systems that keep it running smoothly without the need for constant upkeep.

 

10+ Working Modes & 3 External Controls 

 With over 10 working modes and 3 external control options, you have the flexibility to adjust settings for optimal performance in any scenario.

 

Noise Index ≤ 48dB(A)

Our pump operates at a low noise level, making it perfect for noise-sensitive environments such as homes, offices, and more.

 

High-Performance Bearing Coating with Multiple Protection - Made to last for years!

 Mega S 80-8F features a high-performance bearing coating and multiple protection measures to ensure long-lasting durability and performance.

 

Anti-Resistant & Long-Lasting - Engineered for tough applications!

This pump is resistant to wear and tear, with an expected lifespan of up to 10 years.

 

 Ready to Upgrade?

 

Don't settle for anything less than the best! Visit our website[www.shinhoopump.com] or contact us[info@shinhoopump.com] today to learn more about Shinhoo Mega S 80-8F and how it can revolutionize your fluid circulation needs.

 

Shinhoo, a market-leading provider of advanced water pump solutions, is pleased to announce the launch of its latest innovation: PFM03-30 EC Integrated Water Booster Pump. This cutting-edge water pump boasts a range of pioneering features that guarantee outstanding performance, convenience and reliability.

At the core of this innovative pump is its IE5 motor, which represents a new benchmark in energy efficiency. The motor's exceptional performance not only reduces power consumption but also minimizes environmental impact, making it a sustainable choice for today's world.

PFM03-30 EC introduces variable speed control with digital display, offering users unparalleled freedom to adjust and optimize water flow according to their specific requirements. This feature provides effortless control and ensures maximum efficiency in water distribution systems, thereby saving water and energy resources.

PFM03-30 EC is designed with safety and stability as its core principles, incorporating a range of protection mechanisms to ensure optimal performance. These safeguards guarantee stable pump operation and prevent damage from common issues such as overheating, voltage fluctuations and dry running. The product’s robust design ensures long-lasting performance and provides customers with peace of mind.

PFM03-30 EC is designed with a water cooling structure, which enables it to operate at just 58dB(A), ensuring a remarkably quiet environment. PFM03-30 EC pump is designed to eliminate the annoying noise associated with traditional pumps, offering a quiet and comfortable experience.

Furthermore, the pump is WRAS certified, confirming that it meets the highest quality and safety standards. This certification ensures that the pump is suitable for use with potable water, guaranteeing a clean and reliable water supply in a range of applications.

PFM03-30 EC's self-priming capability provides users with an additional level of convenience and versatility. The pump's powerful suction capacity of up to 8 meters allows users to effortlessly prime it and ensure a consistent water flow, even in challenging situations.

To further optimize operational efficiency, PFM03-30 EC is equipped with an automatic start and stop function. This innovative feature eliminates the need for manual intervention by automatically starting and stopping the pump in response to water demand. This not only streamlines operation but also helps to reduce energy consumption.

PFM03-30 EC Integrated water booster pump from Shinhoo represents a significant advancement in water pump technology. The superior IE5 motor, adjustable speed control, robust protection systems, low noise operation, WRAS certification, self-priming capability and automatic start/stop function combine to provide an exceptional user experience and unparalleled performance.

 

Are you searching for a powerful, reliable, and efficient circulation pump to meet your industrial or commercial needs?

Look no further! Shinhoo is proud to present our latest innovation—Basic Pro 3*380V Let's delve into the details!

Thickened Pump Body

We understand the importance of durability in demanding environments. The Shinhoo Circulation Pump boasts a thickened pump body that ensures enhanced resistance to wear and tear, effectively increasing its operational life.

Stamping One-piece Impeller

Performance is key when it comes to pump efficiency. We've incorporated a precision-engineered, one-piece impeller with exceptional hydraulic capabilities. This design is specifically geared towards maximizing the conveying efficiency of our pump, ensuring optimal performance.

 Multi-layer Paint Protection

We know that corrosion and rust can negatively impact pump performance and reliability. To address this, we have applied a multi-layer anti-corrosion and anti-rust coating to the pump. This exceptional protective finish not only safeguards the pump body but also extends its lifespan, providing you with long-lasting performance.

Self-developed Motors

At Shinhoo, we pride ourselves on delivering excellence at every level. That's why our Basic Pro 3*380V Circulation Pump is equipped with self-developed motors. These motors are meticulously designed and crafted to provide superior power, efficiency, and reliability. Expect nothing less than the best from Shinhoo.

Multi-calibre Coverage Application

We understand that industries have varying requirements. The Shinhoo Circulation Pump is engineered to cater to a wide range of applications, thanks to its multi-caliber coverage. Versatility is at your fingertips, ensuring the pump is suitable for multiple needs within your facility.

 

At Shinhoo, we believe in delivering products that exceed expectations. Our Basic Pro 3*380V Circulation Pump is backed by extensive research, cutting-edge technology, and a commitment to excellence. Harness the power of Shinhoo for your pumping needs and experience unparalleled performance.

Do you wait for hot water? Look no further! SPA 15-12E Instant Hot Water Pump provides hot water in your home instantly. With its remarkable features including instant hot water, quiet operation, safety voltage, built-in timer, and temperature control, this water pump is designed to enhance your overall water experience and streamline your daily routines.

Instant Hot Water Supply

Say goodbye to wasting time and precious water waiting for hot water. With SPA 15-12E, hot water is just a turn of the tap away. This exceptional water pump is designed to deliver hot water instantly, ensuring a seamless experience in your daily activities such as washing dishes, taking showers, or even brewing a cup of tea.

Quiet Operation

We understand the importance of peace and tranquility in your home. That's why SPA 15-12E boasts an impressively quiet operation, with noise levels below 42dB(A). You can enjoy the convenience of instant hot water without any disruptive noise, creating a serene environment for you and your family.

Safety Voltage

Safety is our top priority. SPA 15-12E operates on a safe voltage, providing you with peace of mind. You can confidently use this water pump without worrying about any electrical hazards, making it an ideal choice for home use.

Built-in Timer

Efficiency and convenience go hand in hand with SPA 15-12E. The built-in timer allows you to schedule the pump's operation according to your specific needs. Set it to activate during peak usage hours or customize it based on your daily routines. With this feature, you can optimize energy consumption and ensure hot water is readily available whenever you require it.

Temperature Control

Every individual has different preferences when it comes to hot water temperature. SPA 15-12E offers temperature control functionality, allowing you to adjust the water temperature to your liking. Whether you prefer a soothing warm bath or piping hot water for cleaning purposes, this water pump can cater to your specific needs effortlessly.

 

Don't waste another moment waiting for hot water to arrive. Upgrade your home with SPA 15-12E and enjoy the convenience of instant hot water at your fingertips!

Shinhoo is proud to announce the launch of our latest product line, the Mega Pro Series. As the first manufacturer in our country to adopt TFT LCD display technology in pump production, we are revolutionizing the industry with a range of advanced features and exceptional performance.

High Efficiency & Energy Savings

Our pumps are designed with cutting-edge technology to provide excellent energy efficiency, helping you save on operational costs.

Dual for Heating and Cooling System

The Mega Pro Series offers versatile functionality, allowing you to utilize these pumps for both heating and cooling system, enhancing their overall utility.

Low-Noise

Mega Pro boasts significant advantages in low-noise operation, ensuring a tranquil and serene environment. With noise levels as low as 45 dB(A), our pumps are designed to minimize disturbances and provide a peaceful and comfortable atmosphere for various settings. Whether it's in residential buildings, office spaces, or recreational areas, the low-noise feature of Mega Pro pumps enhances the overall experience.

15 Protection Mechanisms

Safety is a top priority for us, and the Mega Pro Series is equipped with 15 different protection mechanisms to safeguard against potential hazards.

12 Control Modes

Our pumps offer a comprehensive range of control options, including AUTO, AUTO FLOWLIMIT, Constant Speed, Constant Pressure, Proportional, Constant Flow, Temperature Control, Temperature Difference Control, 0-10V, 4-20mA, PWM, and Communication Control.

3 Communication Options

Choose from three communication modes—Modbus, CAN, and LIN—to effortlessly integrate our pumps into your systems.

2 Output Signals

The Mega Pro Series supports two output signal options: PWM and Relay, providing flexibility in connecting to external devices.

3 Terminal Control Signals

Take advantage of the three terminal control signals—Run/Stop Key, Maximum Speed Key, Minimum Speed Key—to easily operate and optimize pump performance.

External Sensor & 24V Power Supply

Our pumps come equipped with a 24V power supply for external sensors, ensuring seamless power delivery to your sensing equipment.

 

The Mega Pro Series represents a significant leap forward in pump technology, delivering unparalleled efficiency, versatility, and reliability. At Shinhoo, we are committed to pushing boundaries and setting new standards in the industry.

Atmospheric pressure and low pressure storage tanks are common equipment in process industry. Atmospheric pressure, low pressure tank in the use of the process often due to changes in the liquid level in the tank, or changes in the external temperature and other reasons, resulting in the expansion or contraction of the gas in the tank, the gas phase pressure in the tank also fluctuates, the fluctuation of gas pressure is easy to make the tank overpressure or vacuum, serious will cause the tank overpressure drum or low pressure dented tank. In order to prevent the instability of the storage tank such as overpressure or negative pressure, the process design usually adopts the way of installing a breathing valve on the top of the tank to maintain the pressure balance of the storage tank, ensure that the storage tank is not damaged during overpressure or vacuum, protect the safety of the storage tank, and reduce the volatilization and loss of the materials in the storage tank, which plays a certain role in promoting safety and environmental protection. The internal structure of the breathing valve is essentially composed of a pressure valve disc (that is, the exhalation valve) and a vacuum valve disc (that is, the suction valve), and the pressure valve disc and the vacuum valve disc can be arranged side by side or overlapping. Its working principle: when the tank pressure and atmospheric pressure are equal, the valve disc of the pressure valve and the vacuum valve are closely matched with the seat, and the sealing structure on the side of the seat has the "adsorption" effect, so that the seat is tight and not leaking. When the pressure or vacuum degree increases, the valve disc begins to open, because there is still a "adsorption" effect on the side of the seat, so it can still maintain a good seal.

When the pressure in the tank rises to a constant pressure value, the pressure valve is opened, and the gas in the tank is discharged into the outside atmosphere through the exhalation valve (that is, the pressure valve). At this time, the vacuum valve is closed due to the positive pressure in the tank. On the contrary, when the pressure in the tank drops to a certain vacuum degree, the vacuum valve opens due to the positive pressure of atmospheric pressure, and the outside gas enters the tank through the suction valve (that is, the vacuum valve), and the pressure valve is closed. At any time, the pressure valve and the vacuum valve should not be open at the same time. When the pressure or vacuum in the tank is reduced to the normal operating pressure state, the pressure valve and the vacuum valve are closed to stop the expiratory or inspiratory process.

The breathing valve plays a sealing role in the normal state, and only begins to work under the following conditions: (1) When the storage tank outputs the material, the breathing valve begins to suck human air or nitrogen into the tank. (2) When the material is filled into the tank, the breathing valve begins to exhale the gas in the tank to the outside of the tank. (3) Due to climate change and other reasons to increase or decrease the steam pressure of the material in the tank, the breathing valve exhales steam or inhales human air or nitrogen (usually called thermal effect). (4) In the event of a fire, the liquid evaporation in the tank increases dramatically due to the heat of the exhaled gas, and the breathing valve begins to exhale out of the tank to avoid damage to the tank due to overpressure. (5) In other working conditions, such as pressurized transportation of volatile liquids, chemical reactions of internal and external heat transfer devices, and operational errors, the breathing valve is exhaled or sucked accordingly to avoid damage to the storage tank due to overpressure or ultra-vacuum.

一、An overview of regulating valves

The regulating valve is used to regulate the flow, pressure, temperature, liquid level and other parameters of the medium.
According to the signal output by the controller, automatically control the opening of the valve, change the adjustment parameters, and control the adjusted parameters within the required range, so as to achieve the process
Production automation.

• Regulating valves are divided into pneumatic, hydraulic and electric according to their energy forms.

• Pneumatic regulating valves are divided into film type, piston type and long-line program according to their actuator form.

• Electric and hydraulic regulating valves are divided into straight stroke and angular stroke according to the movement of the actuator.

At present, pneumatic regulating valves are commonly used in the petrochemical industry, electric regulating valves are rarely used, and hydraulic regulating valves are only used under special requirements.
• Circulation capacity Cw is one of the main parameters for selecting the regulating valve. The circulation capacity of the regulating valve is defined as: when the regulating valve is fully open, when the pressure difference between the two ends of the valve is 0.1MPa, and the fluid density is 1g/cm3, the flow rate flowing through the regulating valve per hour is called the circulation capacity, also known as the flow coefficient, in Cv

It means that the unit is t/h, and the Cv value of the liquid is calculated as follows.

According to the size of the Cv value of the circulation capacity, the nominal diameter DN of the regulating valve can be determined.

• The flow characteristic of the regulating valve is the relationship between the relative flow of the medium flowing through the regulating valve and its opening under the condition that the pressure difference between the two ends of the valve is constant. The flow characteristics of the regulating valve include linear characteristics, equal percentage characteristics and parabolic characteristics. Three kinds of betting special Jie Shangyi Fork League
1) The relative stroke and phase of equal percentage characteristics (logarithm) and equal percentage characteristics

/ There is no linear relationship with the flow. The change of flow caused by the change of the unit stroke at each point of the journey is directly proportional to the flow at this point, and the percentage of the flow change is equal. Therefore, its advantage is that the flow rate is small and the flow change is small. When the flow is large, the flow change is large, that is, it has the same adjustment accuracy at different openings.

(2) Linear characteristics (linear) The relative stroke and relative flow of linear characteristics are linearly related. The flow change caused by the change of the unit itinerary is unchanged.

When the flow is large, the relative value of the flow changes small, and when the flow is small, the relative value of the flow changes greatly.
3) The parabola characteristic flow varies proportionally to the two sides of the stroke, and generally has the intermediate characteristics of linear and equal percentage characteristics.

From the analysis of the three characteristics, it can be seen that in terms of its adjustment performance, the equal percentage characteristics are the best, and its adjustment is stable and the adjustment performance is good. And the parabolic characteristics have better adjustment performance than linear characteristics, and any of the flow characteristics can be selected according to the requirements of different occasions of use.
2./Regulating mechanism:

• The regulating mechanism is mainly composed of a valve core and a valve seat, which is actually a throttle element that can be changed by local resistance. The upper part of the valve stem is connected to the actuator, and the lower part

1 Connected to the valve core. Because the valve spool moves in the valve body, the circulation area between the valve core and the valve seat changes, that is, the resistance coefficient of the valve is changed, and the flow rate of the controlled medium also changes accordingly, so as to achieve the purpose of controlling the process parameters.

• The types of regulating mechanisms mainly include straight-through single-seat, direct double-seat control valves, angular control valves, three-way control valves, diaphragm control valves, butterfly valves, ball valves and cage valves.

I. Valve positioner

The valve positioner is the main accessory of the regulating valve. It is used with the pneumatic regulating valve. It receives the output signal of the regulator, and then the positioner outputs the signal to control the pneumatic regulating valve. When the regulating valve moves, the displacement of the valve stem is fed back to the valve positioner through the mechanical device, forming a closed-loop loop.

According to the types of on-site regulating valve locators, the types, installation and adjustment methods and steps of the locator are summarized. Let's briefly introduce the types of locators and the precautions for installation. The adjustment of the locator will be explained separately as a key part.

1. Types of locators

There are the following types of positioners used in the on-site regulating valve:

(1) ABB single/dual-acting locator;

(2) Fisher DVC6000 series intelligent valve

Door Positioner (3) YT-2400 Intelligent Valve Positioner; (4 Y 00 Series Outlet Valve Positioner (5) Fisher DVC2000 Intelligent Valve Positioner

• Check the installation angle of the feedback bar in the position.

Press and hold the MODE key.

At the same time, click the key or the key until the operation mode code 1.3 is displayed.

Release the MODE button.

Use the public and • keys to make the actuator run to the two terminal positions respectively and record the two terminal angles.

The two angles should conform to the following recommended angle range (the minimum angle displacement is 20 degrees, no strict symmetry is required)

The application range of straight stroke is within -28°--- +28°.

The angular stroke application range is within -570--- +57°.

The angle of the whole journey should not be less than 25°.

I. Valve fire resistance test



According to different usage occasions and product functions, the valve fire resistance test standards are also different. For example, the American Petroleum Institute has formulated the standard ANSI/AP1607 for soft valve seats, the standard API6FA for pipeline valves and wellhead devices, and the standard API6FD for check valves. The International Organization for Standardization has formulated the standard IS010497 for the fire resistance test of various valves, and China has also formulated the standard JB/T6899 for the requirements of various valve fire resistance test systems and methods.

1. General requirements
   
   Although the test requirements for various valves are different, the general requirements of the valve fire resistance test standards are basically the same. In addition to the check valve, the general requirement is that the stem of the tested valve is installed horizontally on the test pipe, and the tested valve is closed. The pipe and the valve under test are filled with water and the water pressure in the system reaches the standard value, ignite the gas fuel and ensure that the tested valve is completely surrounded by fire. The flame temperature around the valve body and the temperature of various parts of the valve body should reach the standard within a certain period of time.
   
   

   Please continue to burn for 30min under the condition that the temperature meets the requirements, and check the internal and external leakage of the valve during the fire and the internal and external leakage of the valve after the combustion and cooling.

   
   
2. Experimental projects
   
   The main leakage indicators and operation requirements of the valve fire resistance test include leakage during fire, leakage outside during fire, low-pressure test after cooling and operation test, etc.
   
   
3. Test standards
   
   API SPEC 6FA Specification for Fire Test for Valves
   
   API SPEC 6FD Specification for Fire Test for Check Valves
   
   API STD 607 Fire test for quarter-turn valves and valves equipped with nonmetallic seats
   
   BS EN ISO 10497 Testing of valves - Fire type-testing requirements
   
   GBT 26482 Check Valve Fire Resistance Test
   
   II. Valve life test
   
   Life test is a method to study the life characteristics of products. It is one of the most important items in the reliability test. It is to put the product
   
   Examine the law of its failure change with time under specific experimental conditions. The valve life test is to test whether the sealing of the valve body and valve seat is good after a certain number of actions under the action of factors such as water flow pressure and mechanical circulation. It is mainly for the sealing performance test of the valve; the static pressure life test for the valve: the operating moment test for the valve.
   
   
4. Test standards
   
   The test standards of valve life test mainly include:
   
   GB/T 26480 "Inspection and Test of Valves"
   
   JB/T 8858 "Test Procedures for Static Pressure Life of Gate Valves"
   
   JB/T 8859 "Stostatic Pressure Life Test Regulations for Shut-off Valve"
   
   JB/T 8860 "Test Regulations for Static Pressure Life of Plug Valve"
   
   JB/T 8861 "Ball Valve Static Pressure Life Test Regulations"
   
   JB/T 8863 "Butterfly Valve Static Pressure Life Test Procedure"
   
   Among them, the static pressure life test procedures of the five types of valves, gate valves, shut-off valves, plug valves, ball valves and butterfly valves define the static pressure life test as "under laboratory conditions, when the valve is subjected to medium pressure, the valve is subjected to the cycle operation test from full opening to full closing." And it is required that the sealing performance of the valve for the static pressure life test meets the requirements of GB/T 13927 or GB/T26480.
   
   III. Low-temperature test of valve
   
   Low-temperature valves usually refer to valves with an operating temperature below -40°C. With the development of air separation, liquefied natural gas, ethylene petrochemical and other industries, in recent years, the market demand for low-temperature valves has increased year by year, and the application field has become more and more extensive. Low-temperature valves have become an important branch of valve products, and the low-temperature test device of valves is an indispensable key equipment in the production process of low-temperature valves. A complete and requirement-compliant valve low-temperature test device is not only a guarantee for the production and quality control of low-temperature valves, but also an important part of low-temperature valve production capacity. Symbol.
   
   Before the low-temperature test, the valve should be degreased and dried, because the grease and moisture return to hard solids in the low-temperature environment, causing structural damage in the valve. After connecting the valve and the test device, use helium to do the initial test under normal temperature and high working pressure to ensure the tightness of the connection of each part. In the process of cooling the valve, hydrogen should always circulate in the valve to take away the moisture that may be formed during the cooling process. The whole test process should be completed in the low-temperature test tank. The valve is immersed in liquid nitrogen as a whole, and the liquid level height should reach the neck of the valve cover. When the temperature of each part meets the specified requirements, the test can be started. The content of the low-temperature test is mainly to test the sealing and operation performance of the valve in the low-temperature state according to the relevant standard requirements, and several switching operations should be done during this period.
   
   
5. Test standards
   
   GB/T 24925-2019 "Technical Conditions for Low-temperature Valves"
   
   BS6364 low-temperature valve
   
   MESC SPE77:200 Low-temperature Valve Specification (Shell Petroleum Company Technical Specification)
   
   

   IV. Valve micro-leakage test

   The test medium uses compound gas, and the micro-leakage of the valve is measured with a helium mass spectrometer leak detector. Usually, a helium mass spectrometer leak detector is required in the valve low-temperature test and the sipative test.
   
   

6. Test standards
   
   ISO 15848-1 Industrial Valves-Measurement, test and qualification procedures for fugitive emissions Part: Classification system and qualification procedures for type testing of valves
   
   ISO 15848-2 Industrial Valves-Measurement, test and qualification procedures for
   
   Fugitive emissions Part2: Production acceptance test of valves
   
   GB/T26481 Dispersion Test of Valve
   
   V. Test of electric actuator
   
   An electric actuator is a drive device that can provide linear or rotational motion, which uses some driving energy and works under the action of some control signal. There are two types of electric actuators, which are generally divided into partially rotating electric actuating mechanisms and multi-rotating electric actuating mechanisms. The former mainly controls valves that need to be partially rotated, such as ball valves, butterfly valves, etc., and the latter requires multi-turn rotating valves, such as gate valves, etc.
   
   
7. Test standards
   
   Technical conditions of G/T 24923 ordinary valve electric device
   
   GBT 28270 Intelligent Valve Electric Device
   
   JB/T8219 Ordinary and intelligent electric actuator for industrial process control system
   
   NB/T20010.11 Pressurized Water Reap Nuclear Power Plant Valve Part 11: Electric Device
   
   BS EN 15714-2 Industrial Valve. Actuator. Part 2: Electric actuator of industrial valves. Basic requirements
   
   JBT 8862 Valve Electric Device Life Test Procedures
   
   DLT 641 Power Station Valve Electric Actuator
   
   

   
   

   
   

Hazards and prevention measures of valve flash explosion

Valve flash explosion refers to the instantaneous violent explosion that occurs inside or around a valve under specific conditions. This type of explosion is usually characterized by suddenness, high intensity, and destructiveness, posing a serious threat to personnel, equipment, and the production environment.

1. Causes of Generation

1.1 Accumulation of Flammable Gases

1.1.1 When there is a leak of flammable in the pipeline system where the valve is located, the flammable gas may accumulate in the enclosed space around the valve. If the concentration of the leaking flammable reaches the explosive limit range, it will cause a flash explosion upon encountering a source of fire.

1.1.2 For example, in pipeline systems conveying flammable gases such as natural and liquefied gas, if the valve seal is not tight, the gas will leak and accumulate in relatively enclosed spaces like the valve well or operating room, forming an explosive hazardous environment.

1.2 Static Electricity Accumulation and Discharge

1.2.1 During the process of fluid (especially flammable liquids) flowing through the valve, electricity may be generated due to the friction between the fluid and the inner wall of the valve, valve core, and other components. If the static electricity cannot be conducted away, it will accumulate to a certain extent. When the energy of the electric spark generated by the static discharge is large enough, it may ignite the surrounding am m able gas or flammable vapor, causing a flash explosion.

1.2.2 For example, in the petrochemical industry, pipeline systems conveying flammable and explosive liquids are prone static electricity at the valves. If there are no good static grounding measures, flash explosion accidents may occur.

1.3 Self-ignition Caused by High Temperature

1.3.1 In some special cases, the valve may experience an increase in local temperature due to external fire sources or heat generated by friction. If there are substances with low selfignition points.

1.3.2 Such as certain flammable dust or oils, near the valve, they may spontaneously ignite under high temperature conditions, leading to a flash explosion. example, in some high-temperature process pipeline systems, if the valve does not have good thermal insulation measures, it may cause the surrounding flammable substances to reach self-ignition temperature, resulting in a flash explosion.

2. Hazards Personnel injuries and fatalities

2.1 Casualties

    The powerful shock wave and flying debris generated by a flash explosion of a valve can cause serious to nearby operators, even endangering their lives. For example, the fragments produced by the explosion may hit the human body, causing cuts, punctures, etc the shock wave may cause people to be thrown up, colliding with surrounding objects, causing fractures, brain injuries, etc.

2.2 Equipment damage

    The flash explosion will cause damage to the valve and surrounding pipelines and equipment. The valve may be blown away or damaged, leading to pipeline rupture and leakage, which can further trigger larger-scale. For example, the flash explosion may destroy the sealing structure of the valve, causing the fluid in the pipeline to leak, polluting the environment, and even fires or explosions.

2.3 Production interruption

The flash explosion of a valve often leads to the interruption of the production system, causing huge economic losses to the enterprise. It takes and money to repair the damaged equipment and pipelines.Meanwhile,the production interruption may also affect the upstream and downstream production processes, causing a chain reaction.

3. Preventive measures

3.1 Prevent combustible gas leakage

3.1.1 Ensure the valve has good sealing performance, conduct regular inspections and maintenance, and promptly replace damaged seals.

3.1.2 Perform pressure tests and leakage detection on the pipeline to timely identify and fix leakage points.
3.2 Electrostatic discharge protection

3.2.1 In the pipeline system conveying flammable and explosive fluids, install electrostatic grounding devices to ensure that static electricity can be timely conducted away.

3.2.2 Control the rate of the fluid to reduce the generation of static electricity.

3.3 Eliminate the source of fire

3.3.1 Strictly control the ignition sources around the valves, prohibit smoking, using open flames, or performing operations that may produce sparks in flammable and explosive.

3.3.2 Design and install electrical equipment with explosion-proof features to prevent electrical sparks from causing flash explosions.

3.3 well ventilated

3.3.1 Ensure that the space where the valve is located is well ventilated to promptly exhaust leaking flammable gases and reduce their concentration.

3.3.2 In places where fl gas accumulation may occur, install flammable gas detection and alarm devices to timely detect dangerous situations and take measures.

3.4 Training and Emergency Management

3.4.1 Provide safety training for operators to enhance their safety awareness and emergency response capabilities.

3.4.2 Develop a comprehensive emergency response plan and conduct regular drills to ensure swift and emergency response in the event of a flash explosion.

1、 Overview

The valve is an important product in the general machinery, which is installed on a variety of pipelines or devices to control the flow of the medium by changing the channel area in the valve. Its role is: turn on or cut off the medium, prevent the medium from countercurrent, adjust the medium pressure and flow parameters, change the flow direction of the medium, divide the medium or carry out overpressure protection on the pipeline and equipment.

  There are many kinds of valve products, which are divided into gate valve, globe valve, check valve, ball valve, butterfly valve, plug valve, diaphragm valve, safety valve, regulating valve (control valve), throttle valve, reducing valve and trap valve according to the function and structure principle; According to the material, there are copper alloy, cast iron, carbon steel, alloy steel, austenitic steel, ferritic-austenitic biphase steel, nickel-based alloy, titanium alloy, engineering plastics and ceramic valves. In addition, there are ultra-high pressure valves, vacuum valves, power station valves, pipeline and pipeline valves, valves for the nuclear industry, valves for ships and low-temperature valves and other special valves. A wide range of valve parameters, nominal sizes from DN1 (in mm) to DN9750; Nominal pressure from 1×10-10mmHg (1mmHg=133.322Pa) ultra-vacuum to PN14600 (unit 105 Pa) ultra-high pressure; The operating temperature ranges from ultra-low temperature of -269℃ to ultra-high temperature of 1200℃.

  Valve products are widely used in various sectors of the national economy, such as oil, natural gas, oil and gas refining and processing and pipeline transportation systems, chemical products, medicine and food production systems, hydropower, thermal power and nuclear power production systems; The water supply and drainage, heating and power supply systems of urban and industrial enterprises, metallurgical production systems, fluid systems of ships, vehicles, aircraft and various moving machinery, irrigation and drainage systems of farmland, etc., all use various types of valves in large numbers. In addition, in the field of new technologies such as defense and aerospace, a variety of valves with special performance are also used.

  The proportion of valve products in mechanical products is larger, according to the statistics of foreign industrial developed countries, the output value of valve accounts for about 5% of the output value of the entire machinery industry. According to statistics, a traditional nuclear power plant consisting of two sets of million-kilowatt units shares about 28,000 valves, of which about 12,000 are nuclear island valves. A modern large-scale petrochemical complex needs more than 100,000 sets of various valves, and the investment for valves generally accounts for 8% to 10% of the total investment in equipment.

2、The general situation of the valve industry in old China

  After the Opium War, old China was in a semi-feudal and semi-colonial society for a long time, and the industrial base was very weak, and the valve industry was especially backward. In the late 19th century, imperialist countries such as Britain and the United States dumped various valves to our country through comprador. At that time, the name of the Valve was unknown, and the commercial common name was called "Val" (the translation of valve). The common name of "Val" has become a well-known substitute name in our country. The "Glasses" brand, "Ostrich" brand and the "W" brand and "C" brand made in the United States have flooded the Chinese market. Until the eve of the founding of New China, our country has not yet got rid of this situation of relying entirely on imports of "Val".

01 The birthplace of China valve industry: Shanghai

In old China, Shanghai was the earliest place to manufacture valves. In 1902, Pan Shunji Copper Workshop, located in Wuchang Road, Hongkou District, Shanghai, began to manufacture small quantities of teapot taps by hand. Teapot taps are a kind of cast copper cock. Pan Shunji Copper Workshop is the earliest valve manufacturer known in China so far. In 1919, Deda (Shengji) Hardware Factory (predecessor of Shanghai Gearshift Machinery Factory), started from a small bicycle bed, opened the production of small-caliber copper cock, stop valve, gate valve and fire faucet. The manufacture of cast iron valves began in 1926, with a maximum nominal size of NPS6 (in, NPS1= DN25.4). During this period, Wang Yingchang, Dahua, Lao Demao and MAO Xu and other hardware factories have also opened to manufacture valves. Subsequently, due to the increase in demand for water heating valves on the market, there are a number of hardware factories, iron factories, foundry (casting) factories and machine factories have opened to manufacture valves. In Shanghai Hongkou District, Hongqiao, Hongqiao, Daiming Road and Changzhi Road area to form a valve manufacturing group. At that time, the best-selling in the domestic market have "horse head" brand, "three 8" brand, "three 9" brand, "double money" brand, "iron anchor" brand, "chicken ball" brand and "eagle ball" brand and other low-pressure casting copper, cast iron valve products, mainly used in building sanitation facilities with water heating valves, there are also a small number of cast iron valves for textile industry. These factories are very small, backward technology, simple plant equipment, valve output is very low, but it is the earliest birthplace of China's valve industry, and later the Shanghai building hardware Industry Association was established, these valve manufacturers have to join, become a member of the waterway group.

  02 Two large valve manufacturers

At the beginning of 1930, Shanghai Shenhe Machinery Factory manufactured low pressure cast iron gate valves below NPS12 for waterworks. In 1935, the factory jointly built Daxin Iron Factory (predecessor of Shanghai Bicycle Factory) with Xiangfeng Iron Pipe Factory and shareholders of Xiangtai Iron No., which was completed and put into operation in 1936. With imported 2.6 zhang (1 zhang ≈3.33m) lathe and lifting equipment, the main production of industrial and mining accessories, cast iron pipes and cast iron valves, the nominal size of the valve is NPS6 ~ NPS18, and can design and supply complete sets of valves for waterworks, products are exported to Nanjing, Hangzhou and Beijing and other places. In 1937, after the "813" Japanese invaders occupied Shanghai, most of the plant equipment was destroyed by Japanese artillery fire, and the following year, although it had also made NPS14 ~ NPS36 cast iron gate valves for Shanghai Zhabei, Nanshi Water works and British and French commercial water works, but due to economic depression, slow business, austerity and layoffs, On the eve of the founding of the People's Republic of China, it still failed to recover. In 1935, by the national businessman Li Chenghai and other five shareholders joint venture to build Shenyang Chengfa iron factory (the predecessor of Tieling Valve Factory) in the twelve Wei Road in the southern district of Shenyang, started from three houses and three machine tools, began to engage in mechanical repair and manufacture valves. 1939 Moved the factory to Tiexi North Second road for expansion, new casting, machining two large workshops. By 1945, it developed to have 400 employees, the main products are: large full boiler, cast copper valves, nominal size of underground cast iron gate valves below DN800. Shenyang Chengfa Iron Factory is a valve manufacturer struggling to survive in old China.

03 The valve industry in the rear

   During the War of Resistance, many enterprises in Shanghai and other places moved to the southwest, so the enterprises in Chongqing and other places in the rear area soared, and the industry began to develop. In 1943, Chongqing Hongtai Machinery Factory and Huachang Machinery Factory (both factories are the predecessor of Chongqing Valve Factory) began to repair and manufacture plumbing parts and low-pressure valves, which played a great role in the development of wartime production in the rear area and the solution of civilian valves. After the victory of the Anti-Japanese War, there were Lisheng Hardware Factory, revitalizing Industrial Society, Jinshun and hardware factory and Qiyi Hardware Factory successively opened to produce small valves, and these factories were incorporated into Chongqing Valve Factory after the establishment of New China. At that time, some valve manufacturers in Shanghai also went to Tianjin, Nanjing and Wuxi and other places to build factories to repair and manufacture valves. Some hardware factories, iron pipe factories, machine factories or shipyards in Beijing, Dalian, Changchun, Harbin, Anshan, Qingdao, Wuhan, Fuzhou and Guangzhou have also been engaged in repairing and manufacturing valves for water heating buildings.