Solenoid Valve Applications: A Complete Guide for Industrial, Commercial, and Automation Systems

Solenoid valves represent one of the most widely deployed electromechanical flow control devices in modern industrial systems. Their fundamental advantage — the ability to convert an electrical signal into precise mechanical valve actuation within milliseconds — makes them indispensable in applications where automation, speed, and repeatability are critical requirements.

However, selecting the correct solenoid valve for a given application demands careful consideration of multiple interdependent parameters: media type and chemistry, operating pressure range, ambient and fluid temperature, duty cycle, electrical characteristics, and environmental classifications. A mismatch in any single parameter can result in premature failure, process downtime, or safety hazards.

This reference guide provides an engineering-level analysis of ten major solenoid valve application domains, with detailed selection criteria, material compatibility data, and practical system integration considerations.

1. Operating Principle & Classification

A solenoid valve actuates through electromagnetic force generated by an energized coil. When current passes through the coil winding, the resulting magnetic field displaces a ferromagnetic plunger within the valve body. This plunger is mechanically coupled to a seal element — typically an elastomeric diaphragm or poppet — which opens or closes the fluid passage.

In a normally closed (NC) configuration, the spring-loaded seal blocks the orifice when de-energized. Energizing the coil lifts the plunger, permitting flow. In a normally open (NO) configuration, the seal is held open by spring force when de-energized, and the coil closes the valve when energized.

Solenoid valves are further classified by their operating mechanism, which critically determines their suitability for different pressure conditions:

2. Direct-Acting vs Pilot-Operated: Critical Selection Criterion

The distinction between direct-acting and pilot-operated solenoid valves is the single most important classification for system designers. Selection errors at this stage are the leading cause of field failures and installation returns.

Parameter Direct-Acting Pilot-Operated
Minimum Operating Pressure 0 bar (0 PSI) — functions under vacuum or gravity feed 0.2–0.35 bar (3–5 PSI) differential pressure required
Actuation Mechanism Coil directly lifts the plunger and seal against spring force Coil opens a pilot orifice; fluid pressure difference lifts the main diaphragm
Response Time 10–30 ms 50–500 ms
Power Consumption Higher (coil provides all actuation force) Lower (coil only opens pilot; fluid pressure provides main force)
Maximum Orifice Typically 2–3 mm diameter Up to 50 mm diameter in large industrial sizes
Flow Capacity (Cv) Low to moderate Moderate to high
Cost (Equivalent Pipe Size) Higher Lower
Typical Applications Gravity-fed systems, vacuum, low-pressure gas, dosing, tank drainage Municipal water supply, pump-pressurized lines, irrigation, industrial washing
Design Constraint: Pilot-operated valves cannot function in gravity-fed or near-zero-pressure systems. The diaphragm requires a sustained differential pressure of at least 0.2 bar across the valve to lift. In such systems, the solenoid will audibly actuate but no flow will occur. Direct-acting valves are mandatory for zero-pressure applications.
Engineering Guideline: If the system includes a pump generating positive pressure, a pilot-operated valve is generally suitable and more economical. If the system relies on gravity or operates under vacuum, specify a direct-acting type.

3. Water Treatment Systems

Water treatment represents the largest installed base of solenoid valves across both municipal and industrial sectors. These systems demand reliable, contamination-free automation with specific material requirements depending on water chemistry and purity requirements.

Application Sub-Domains

  • Reverse Osmosis (RO): Inlet shut-off, automatic membrane flushing, permeate diversion, concentrate flow control
  • Water Softening: Brine draw control during regeneration, automated backwash sequencing
  • Multi-Media Filtration: Automatic backwash initiation, filter bed fluidization control
  • Distribution Systems: Tank level control, pump protection interlocks, zone isolation
  • Deionization (DI): Resin bed regeneration valving, quality-divert control based on conductivity

Engineering Specifications

0–1.0 MPa
Operating Pressure Range
0–80°C
Temperature Range (Standard)
VITON (FKM)
Seal Material
Brass / 304 SS
Body Material
Material Considerations for Water Quality: Brass solenoid valves are not recommended for drinking water (potable) applications due to the risk of lead leaching and dezincification in chlorinated municipal water (>2 ppm free chlorine). For potable water systems, 304 or 316 stainless steel body construction is required. VITON (FKM) is the primary seal material in standard product configurations; EPDM or silicone seals may be specified where available for drinking water compatibility.

4. HVAC & Refrigeration Systems

In heating, ventilation, air conditioning, and refrigeration systems, solenoid valves serve as the primary electrically-actuated flow control elements for both heat transfer fluids and refrigerants. Their selection directly impacts system energy efficiency, temperature stability, and equipment longevity.

System Integration Points

  • Chillers: Condenser water modulation, evaporator bypass, hot gas bypass for capacity control
  • Cooling Towers: Make-up water control, basin drain automation, chemical treatment injection
  • Boilers: Feed water control, bottom blowdown automation, condensate return isolation
  • Heat Pumps: Reversing valve pilot actuation, defrost cycle refrigerant management
  • Air Handling Units: Chilled/hot water coil isolation, face-and-bypass damper control
Refrigerant Compatibility: Standard solenoid valves are not rated for refrigerant service. Refrigerant-rated valves incorporate seals compatible with specific refrigerants — typically PTFE, HNBR, or neoprene — and must be matched to the refrigerant type (R-22, R-134a, R-410A, R-32, R-290, etc.). Incompatible seals will swell, crack, or dissolve upon refrigerant exposure.

Key Design Parameters for HVAC Solenoid Valves

  • Temperature range: -40°C to +180°C depending on media (chilled water, heating hot water, or steam)
  • Seal selection: EPDM for hot water ≤120°C; PTFE for steam ≤180°C
  • Coil insulation class: Class F (155°C) for standard mechanical rooms; Class H (180°C) for high-ambient installations
  • Valve body material: Brass for indoor standard conditions; 304 SS for outdoor or corrosive atmosphere
  • Enclosure rating: IP65 minimum for outdoor or wash-down locations

5. Industrial Automation & Pneumatic Systems

In industrial automation, solenoid valves function as the electromechanical interface between control systems — PLCs, DCS, microcontrollers, and relay logic — and fluid power actuators. They translate low-power electrical signals into pneumatic or hydraulic mechanical work.

Application Categories

  • Pneumatic Actuator Control: 5/2 and 5/3 directional control valves for single- and double-acting cylinders
  • Packaging Machinery: High-speed air blast timing for carton forming, labeling, filling, and sorting operations
  • Automated Assembly: Clamping, pressing, ejection, and part-present verification systems
  • Robotic End Effectors: Gripper actuation, vacuum cup control, tool changer pneumatics
  • CNC / Machine Tools: Coolant flow control, chip removal air blast, spindle purge, tool clamping

Cycle Life Requirements

In continuous production environments, solenoid valves may accumulate 50,000–100,000 cycles per day, translating to 18–36 million cycles annually. Valve selection must account for rated mechanical life:

  • Standard industrial solenoid valves: 1–5 million cycles (suitable for intermittent or batch operations)
  • High-cycle rated valves: 20–50 million cycles (reinforced diaphragms, hardened plunger assemblies)
  • Pneumatic-specific spool valves: 50–100+ million cycles (hard-coated aluminum spools with specialized dynamic seals)
Control System Interface: Pneumatic solenoid valves for automation are commonly available in both 12V DC and 24V DC configurations. 12V DC is the highest-volume option in many product lines due to widespread power supply availability; 24V DC remains standard for industrial control panels. Coil surge suppression (flyback diodes for DC, varistors for AC) should be integrated to protect PLC output modules from inductive voltage spikes.

6. WiFi-Enabled Solenoid Valves: IoT Integration

WiFi-integrated solenoid valves represent the convergence of fluid control and networked automation. By embedding wireless communication modules directly into the valve actuator, these systems eliminate the need for separate controllers, relay interfaces, and field wiring — enabling remote operation, scheduling, and monitoring through cloud platforms.

Deployment Scenarios

  • Smart Irrigation: Weather-responsive scheduling, multi-zone control with rain/freeze sensor integration, evapotranspiration-based watering
  • Remote Water Shut-Off: Whole-building protection for vacation properties, insurance compliance, leak sensor integration
  • Smart Home Water Management: Usage analytics, anomaly detection, consumption reporting
  • Leak Protection: Floor sensor network integration, automatic main valve closure, real-time push notification
  • Aquaculture / Hydroponics: Automated water exchange, nutrient dosing, flood prevention interlocks

Technical Specifications

2.4 GHz
WiFi Standard (802.11 b/g/n)
5V DC (USB powered)
Operating Voltage
0–1.0 MPa
Pressure Range
DN15–DN40
Available Port Sizes
Power Management for Battery/Solar Installations: WiFi modules and continuously-energized solenoid coils together consume 5–15 watts. For battery-powered or solar installations, latching (bi-stable) solenoid valves are strongly recommended. These valves require power only during the switching transient (typically 50–200 ms) and maintain their state via permanent magnet hold — enabling months of operation from a single battery charge.

7. High-Pressure Solenoid Valve Applications

While standard solenoid valves operate in the 0–1.0 MPa (0–145 PSI) range, high-pressure variants are engineered for applications requiring elevated pressure ratings. These valves incorporate reinforced body construction, specialized high-strength seals, and small-diameter orifices to manage the increased mechanical loads imposed by high-pressure media. U.S. Solid high-pressure solenoid valves are rated up to 50 bar / 5 MPa (725 PSI) in brass body construction and up to 100 bar / 10 MPa (1,450 PSI) in 316 stainless steel body construction.

Application Domains

  • Water Jet Cutting: On/off abrasive water jet control at 30–60 ksi; for these extreme-pressure applications (>200 MPa), specialized ultra-high-pressure valving with metal-to-metal or PEEK seals is required — standard solenoid valves are not suitable at this pressure tier
  • Hydraulic Power Units: Pilot control, accumulator dump, emergency shut-off, and load-holding circuits
  • Pressure Testing: Automated pressure hold and release cycling for pipe, vessel, and component certification
  • Industrial Cleaning: High-pressure washer pump discharge control (10–25 MPa for heavy equipment and surface preparation)
  • Fuel Injection Test Equipment: Diesel injector performance characterization requiring precise high-pressure fuel delivery

Engineering Requirements

  • Body Material: 316 stainless steel minimum; duplex stainless or Inconel alloys for extreme pressure/corrosion combinations
  • Seal Material: PTFE seals — the standard sealing element in U.S. Solid high-pressure valve configurations. PTFE provides excellent chemical resistance and high-temperature stability without the extrusion risk associated with softer elastomers under high differential pressure.
  • Orifice Sizing: U.S. Solid high-pressure valves feature orifice sizes of 12 mm (brass, 50 bar) and 25 mm (316 SS, 100 bar). For pressures exceeding 100 bar, smaller orifice designs (0.2–2.0 mm) are typically required to manage sealing forces — this is an industry-standard design trade-off, not applicable to U.S. Solid's current product range.
  • Safety Factor: Minimum 1.5× maximum operating pressure; 2.0× recommended for cyclic or fatigue-sensitive installations
  • Temperature Range (U.S. Solid): Brass body: -5°C to 150°C (23°F–302°F); 316 SS body: -60°C to 120°C (-76°F–248°F)

8. Corrosion-Resistant Solenoid Valves: Chemical & Aggressive Media

When the process fluid is chemically aggressive — acids, bases, oxidizers, or organic solvents — standard brass or stainless steel valves degrade rapidly through corrosion, pitting, or seal dissolution. Corrosion-resistant solenoid valves employ chemically inert polymer bodies and specialized elastomers to provide long-term reliability in these demanding environments.

Application Domains

  • Chemical Dosing: Precision injection of acids, caustics, oxidizers, and coagulants into process or treatment streams
  • Electroplating: Plating solution distribution, rinse water automation, waste stream segregation
  • Bulk Chemical Transfer: Inter-tank chemical movement in processing and storage facilities
  • Wastewater pH Adjustment: Automated acid/base injection controlled by pH sensor feedback loops
  • Semiconductor Fabrication: Ultra-high-purity chemical delivery requiring fluoropolymer wetted surfaces (CPVC or PTFE)

Material Selection Matrix

Product Availability Note: U.S. Solid's current corrosion-resistant solenoid valve product line is based on CPVC body construction. The full material matrix below is provided as an industry reference for engineering selection across different chemical environments.
Media Classification Body Material Seal Material Maximum Temperature
Dilute mineral acids (HCl, H₂SO₄ ≤30%) UPVC / CPVC PTFE / EPDM 60°C (UPVC) / 95°C (CPVC)
Concentrated acids PVDF PTFE 120°C
Alkaline solutions (NaOH, KOH) UPVC / 316 SS EPDM / PTFE 60°C (UPVC) / 150°C (316 SS)
Oxidizing agents (H₂O₂, NaOCl, Cl₂) PVDF / PTFE PTFE 100°C
Organic solvents 316 SS / PVDF FKM / PTFE Application-dependent
Ultra-pure water (semiconductor grade) PVDF / PTFE PTFE 100°C

9. Explosion-Proof Solenoid Valves: Hazardous Area Classification

In environments where flammable gases, vapors, or combustible dusts may be present, any electrical device — including a solenoid valve coil — constitutes a potential ignition source. Explosion-proof solenoid valves are designed and certified to contain any internal arc or spark within a flameproof enclosure, preventing ignition of the surrounding atmosphere.

Hazardous Area Applications

  • Oil & Gas Production: Wellhead control panels, separator level control, gas compression station valving
  • Fuel Storage & Distribution: Tank farm automation, loading rack control, leak detection system isolation
  • Petrochemical Processing: Reactor feed control, solvent transfer, vapor recovery systems
  • Paint & Coating: Paint supply line shut-off, solvent flush control, spray booth automation
  • Pharmaceutical Manufacturing: Solvent handling in classified production areas

Engineering Specifications (U.S. Solid)

0–0.8 MPa
Operating Pressure
≤60°C
Media Temperature
-20°C to +45°C
Ambient Temperature
Brass / 24V DC
Body Material / Voltage
Product Scope: U.S. Solid explosion-proof solenoid valves are currently available in brass body construction with 24V DC coil configuration. Stainless steel and other voltage options may be available through custom order — consult product listings for current availability.

Understanding Explosion-Proof Markings

Marking Element Designation Meaning
Protection Concept Ex d Flameproof enclosure — contains any internal explosion and prevents flame propagation
Gas Group IIC Suitable for hydrogen and acetylene (most easily ignited gases); also covers IIB (ethylene) and IIA (propane)
Temperature Class T6 Maximum surface temperature ≤85°C — safest temperature class, suitable for all gas groups
Equipment Protection Level Gb Suitable for Zone 1 (areas where explosive atmospheres are likely to occur in normal operation)
Safety-Critical Requirement: Non-certified solenoid valves must never be installed in classified hazardous areas. The electrical arc generated during normal coil switching is sufficient to ignite flammable atmospheres. Certification must be verified against the specific zone classification, gas group, and temperature class of the installation location.

10. Proportional Solenoid Valves: Modulating Flow Control

Unlike discrete on/off solenoid valves, proportional solenoid valves provide continuously variable flow control by modulating the coil current. The plunger position — and consequently the effective orifice area — varies proportionally to the applied control signal, enabling closed-loop flow, pressure, or position regulation.

Application Domains

  • Medical Devices: Anesthesia gas mixing, ventilator flow regulation, dialysis machine fluid management
  • Analytical Instrumentation: Gas chromatography carrier gas control, mass spectrometer sample introduction
  • Precision Dispensing: Pharmaceutical ingredient batching, food additive injection, fragrance and flavor blending
  • Process Control: pH adjustment via reagent flow modulation, temperature control through heat transfer fluid regulation
  • Fuel Cell Systems: Hydrogen and oxygen stoichiometry control for PEM fuel cell stack optimization

Performance Parameters

<5%
Hysteresis (Typical)
<2%
Hysteresis (Precision)
5–50 ms
Response Time
PWM
Control Signal

U.S. Solid Proportional Valve Specifications

6 bar
Maximum Pressure
-10°C to 90°C
Media Temperature
0°C to 55°C
Ambient Temperature
0.8 / 1.0 / 1.2 mm
Orifice Sizes

11. Vacuum System Solenoid Valves

Vacuum applications impose unique sealing demands: the valve must prevent atmospheric air from leaking into the evacuated system, rather than preventing pressurized media from leaking out. Standard pressure-rated solenoid valves frequently fail under vacuum because their seal geometry and material selection are optimized for positive pressure differentials in the opposite direction.

Application Domains

  • Vacuum Packaging: Food and pharmaceutical vacuum sealing machines requiring reliable chamber vent and pump isolation
  • Laboratory Equipment: Vacuum ovens, rotary evaporators, Buchner filtration manifolds
  • Semiconductor Manufacturing: Wafer handling via vacuum chuck control, process chamber vent valves, load-lock isolation
  • Vacuum Coating: PVD/CVD chamber gas inlet control, roughing pump isolation
  • Medical Suction Systems: Central vacuum supply zone control, surgical suction regulation

Design Requirements

  • Seal Orientation: Vacuum-rated valves are designed with seals that function under reverse pressure differential. Verify the valve is explicitly rated for vacuum service; bi-directional ratings are acceptable for moderate vacuum.
  • Leak Rate: Specified as ≤1×10⁻³ Pa·m³/s for rough/medium vacuum; ≤1×10⁻⁷ Pa·m³/s for high vacuum applications
  • Outgassing: Low-outgassing materials are essential for high-vacuum applications. While EPDM or FKM (Viton) are the preferred elastomers for high or ultra-high vacuum service, NBR seals are suitable for vacuum use with air and water media at standard temperatures. Note: U.S. Solid vacuum solenoid valves are supplied with NBR seals as standard.
  • Body Material: Stainless steel or brass. Polymer body valves are generally unsuitable beyond rough vacuum due to permeation and outgassing.

12. High-Temperature Solenoid Valve Applications

Standard solenoid valves are rated for media temperatures of 0 to 80°C. High-temperature variants extend this range to 200°C and beyond, incorporating thermally-stable seal materials, high-temperature coil insulation, and in some designs, thermal isolation between the fluid path and the solenoid assembly.

Application Domains

  • Steam Systems: Sterilization autoclaves, humidification steam injection, process steam control, steam tracing
  • Boiler Plants: Feedwater preheat control, continuous blowdown automation, condensate return management
  • Thermal Oil Systems: Heat transfer fluid circulation control, heat exchanger bypass regulation
  • Food Processing: Cooking vessel steam supply, CIP (Clean-in-Place) hot water and chemical solution valving
  • Textile Processing: Dyeing machine steam control, finishing equipment temperature regulation

Temperature Classification & Seal Selection

Temperature Range Seal Material Suitable Media
0–80°C NBR (Nitrile) Cold water, compressed air, light mineral oils
0–120°C EPDM Hot water, low-pressure saturated steam, HVAC fluids
-20–150°C FKM (Viton) Hot oils, hydrocarbon fuels, selected chemicals
-40–200°C PTFE (Teflon) Saturated steam, aggressive chemicals, high-purity media
>200°C (Specialty) Graphite / Metal Superheated steam, high-temperature thermal oils

13. Solenoid Valve vs Motorized Ball Valve: Application-Driven Selection

Both solenoid valves and motorized ball valves provide electrically-actuated flow control, but they serve fundamentally different operating profiles. Selection between them should be governed by duty cycle, flow requirements, pressure drop tolerance, and switching frequency.

Parameter Solenoid Valve Motorized Ball Valve
Actuation Speed 10–500 ms 3–15 seconds
Flow Path Design Orifice-restricted (does not maintain full pipe ID) Full port / full bore (zero diameter reduction)
Continuous Duty Capability Limited — coil heats during sustained energization (except latching types) Unlimited — motor operates only during switching; holds position without power
Pressure Drop Significant (restricted orifice) Negligible (full bore, equivalent to straight pipe)
Cycle Life 1–50 million cycles (application-dependent) 50,000–200,000 cycles (gear train and motor wear)
Minimum Operating Pressure 0 PSI (direct-acting); 3–5 PSI (pilot-operated) 0 PSI (mechanical actuation independent of fluid pressure)
Relative Cost Lower (especially at smaller sizes) Higher (motor, gearbox, limit switches)
Optimal Use Case High-frequency switching, fast response, compact installation Long-duration hold states, unrestricted flow, zero-pressure applications
Selection Guideline: Specify a solenoid valve when the application requires rapid, frequent switching where some flow restriction is acceptable. Specify a motorized ball valve when the valve must remain open or closed for extended periods with minimal flow resistance — particularly in gravity-fed or low-pressure systems where every fraction of head pressure is significant.

14. Systematic Valve Selection Decision Tree

The following five-step decision framework provides a structured methodology for narrowing valve selection based on application parameters.

Step 1 — Media Characterization
Water / Air → Brass + NBR/VITON Hot Water / Steam → Brass/SS + PTFE Fuels / Hydrocarbons → SS + FKM Acids / Caustics → CPVC + PTFE Potable Water → SS + VITON/EPDM
Step 2 — Operating Pressure Assessment
Pump-pressurized (>35 kPa / 5 PSI) → Pilot-Operated acceptable Gravity-fed / Low pressure → Direct-Acting mandatory Vacuum → Vacuum-rated Direct-Acting mandatory High pressure (>10 MPa) → Reinforced SS body + PTFE seals
Step 3 — Duty Cycle & Switching Frequency
High-frequency cycling (>100/day) → Solenoid Valve Long-duration hold (hours/days) → Motorized Ball Valve Continuous energized state → Latching Solenoid or Motorized Ball Valve
Step 4 — Electrical Supply & Control Interface
AC mains (110V/220V) → AC coil (higher inrush, audible hum possible) DC supply (12V/24V) → DC coil (quiet, cooler operation) Battery / Solar / Low power → Latching (bi-stable) type
Step 5 — Environmental Conditions
Ambient >50°C or Media >120°C → High-temperature coil + PTFE seals Hazardous area (Zone 1/2) → ATEX/IECEx certified Ex d Outdoor / Wash-down → IP65 minimum enclosure Submerged / Flood-prone → IP67 or IP68 rated

15. Body Material & Seal Engineering Reference

Material selection determines both chemical compatibility and mechanical durability of the valve assembly. The following reference tables provide guidance for body and seal material specification across common media types.

Industry Reference & Product Availability: The following tables are provided as an industry engineering reference for material selection across diverse media types. U.S. Solid's current product line covers brass, 304/316 stainless steel, and CPVC body materials. Additional materials listed (UPVC, PVDF, PTFE-lined) are included for completeness as they may be specified for specialized environments where commercially available.

Valve Body Material Selection

Material Recommended Applications Contraindications Relative Cost
Brass Water, compressed air, light oils, neutral aqueous solutions Acids, ammonia, chlorinated water (>2 ppm free Cl₂), seawater Low
304 SS Food/beverage, potable water, general corrosion resistance Chloride-rich environments (pitting corrosion); concentrated reducing acids Medium
316 SS Marine, chemical processing, pharmaceutical, chloride-containing media Concentrated sulfuric and hydrochloric acids at elevated temperatures High
UPVC Dilute acids, alkalis, salt solutions, wastewater Organic solvents, media exceeding 60°C, UV exposure (unprotected) Low
CPVC Hot corrosive media (≤95°C), industrial chemical lines Organic solvents, esters, ketones Low–Medium
PVDF Strong acids, ultra-pure chemicals, high-temperature corrosives Fuming sulfuric acid, molten alkali metals High
PTFE (Teflon) Near-universal chemical resistance Limited mechanical strength (typically used as lining); not for structural applications Highest

Seal Material Chemical Compatibility

Seal Material Temp. Range Compatible Media Incompatible Media
NBR (Nitrile) -20 to 80°C Water, air, mineral oils, LPG, aliphatic hydrocarbons Ozone, strong acids, brake fluid, ketones, esters, chlorinated solvents
EPDM -20 to 120°C Hot water, steam (≤120°C), detergents, brake fluid, polar solvents, dilute acids Mineral oils, fuels, hydrocarbon solvents, greases
FKM (Viton) -20 to 150°C Fuels, mineral/synthetic oils, aliphatic/aromatic hydrocarbons, many chemicals Steam >120°C, ketones (MEK, acetone), esters, low-molecular-weight organic acids
PTFE (Teflon) -40 to 200°C Near-universal — all common industrial chemicals, solvents, acids, and bases Molten alkali metals, elemental fluorine gas at elevated temperature
Graphite -200 to 450°C Superheated steam, high-temperature thermal oils, molten salts Strong oxidizing agents at high temperature (concentrated HNO₃, H₂O₂)

For a comprehensive analysis of seal material selection, refer to: Seal Material Selection Guide — U.S. Solid Technical Reference.

Engineering Support & Product Selection

U.S. Solid maintains a comprehensive inventory of industrial-grade solenoid valves across all application categories covered in this reference. For application-specific selection assistance or technical specifications, contact our engineering team.

Browse Complete Valve Catalog →
Direct-Acting Solenoid Valves Pilot-Operated Solenoid Valves High-Pressure Valves WiFi Smart Valves Explosion-Proof Valves Corrosion-Resistant Valves
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