Блог около Expansion Valve Critical Yet Overlooked in AC Systems

During scorching summer months, air conditioning systems become essential for maintaining indoor comfort. While often overlooked, one component plays a pivotal role in these systems—the expansion valve. Functioning as the refrigeration system's "throttle valve," it precisely regulates refrigerant flow and pressure, directly impacting cooling efficiency and energy consumption. This article examines the working principles, common malfunctions, maintenance requirements, and replacement considerations for this crucial component.

The expansion valve (also called a throttle valve) ranks among the four primary components in refrigeration systems (compressor, condenser, expansion valve, evaporator). Positioned between condenser and evaporator, its primary function involves reducing pressure from high-pressure liquid refrigerant exiting the condenser and regulating it to a low-pressure gas-liquid mixture state. This enables heat absorption through vaporization in the evaporator, achieving cooling effects. The valve's performance critically influences cooling efficiency, energy consumption, and operational stability.

Based on control mechanisms and structural characteristics, expansion valves primarily classify into these categories:

• Thermostatic Expansion Valve (TXV): The most widely used type employs a sensing bulb to detect superheat at the evaporator outlet, automatically adjusting valve opening to regulate refrigerant flow. TXVs offer simple structure, high control precision, and strong adaptability.
• Electronic Expansion Valve (EEV): Utilizing a stepper motor to drive the valve core, EEVs precisely adjust opening via electronic controllers. By monitoring system parameters (evaporator pressure/temperature, compressor discharge temperature), they achieve intelligent flow regulation with superior efficiency and energy savings. Though structurally complex and costly, EEVs outperform TXVs in precision and energy conservation.
• Capillary Tube: This simple throttling device consists of a narrow, elongated copper tube. Flow regulation occurs through inherent resistance as refrigerant passes, causing significant pressure drop. While inexpensive and simple, capillary tubes offer poor flow adjustment and susceptibility to ambient temperature and refrigerant charge variations. They typically serve small AC units or refrigerators.
• Automatic Expansion Valve (AXV): AXVs adjust opening based on evaporator pressure feedback. Lower pressure increases valve opening (greater flow), while higher pressure reduces it. Though simpler and more reliable than TXVs, AXVs demonstrate inferior control precision.

Expansion valves perform these critical functions:

• Pressure Reduction: Lowers high-pressure liquid refrigerant to evaporator-required low pressure, enabling vaporization heat absorption.
• Flow Regulation: Automatically adjusts refrigerant volume based on evaporator load changes, ensuring optimal heat absorption.
• Pressure Maintenance: Sustains appropriate evaporator pressure for stable operation and cooling performance.
• Liquid Slug Prevention: Blocks liquid refrigerant from entering compressors, avoiding damaging liquid slugging.

Comprising sensing bulb, capillary tube, valve body, core, and adjustment mechanism, TXVs operate on thermal equilibrium principles. The sensing bulb detects evaporator outlet superheat, using this signal to modulate valve opening.

Operation sequence:

1. The bulb (filled with refrigerant-matching fluid) senses superheat increases, causing internal pressure rise.
2. Pressure transmits via capillary to the valve diaphragm, generating downward force.
3. Diaphragm force overcomes spring resistance, pushing the core downward to enlarge opening.
4. Increased refrigerant flow enhances evaporator heat absorption, reducing superheat.
5. Upon reaching set superheat, bulb pressure decreases, allowing spring to partially close valve—achieving equilibrium.

EEVs contain stepper motors, valve cores, sensors, and electronic controllers. The controller processes sensor data (evaporator pressure/temperature, compressor discharge temperature) and executes preprogrammed strategies to position the valve core via motor commands.

Operation sequence:

1. Sensors collect real-time system parameters.
2. The controller analyzes data and computes required valve position.
3. Stepper motors adjust core position to regulate flow.
4. Precise refrigerant modulation optimizes cooling capacity.

Obstructions (debris, contaminants, ice) in valve cores or orifices restrict or halt refrigerant flow.

Causes: Poor system cleanliness, impure refrigerant, failed filters, internal corrosion.

Symptoms: Poor cooling, evaporator frosting, compressor overheating, abnormal pressure differentials.

Solutions: System cleaning, refrigerant replacement, filter renewal, or complete valve replacement.

Leaks occur at connections or through valve body defects.

Causes: Loose fittings, degraded seals, body corrosion.

Symptoms: Reduced cooling, low refrigerant pressure, oil traces near leaks.

Solutions: Tightening connections, seal replacement, or valve replacement.

Complete operational breakdown prevents proper flow regulation.

Causes: Stuck cores, defective sensing bulbs (TXV), motor/controller faults (EEV).

Symptoms: Inadequate cooling, evaporator frosting, compressor overheating.

Solutions: Core cleaning, component replacement, or complete valve renewal.

• Regular system cleaning to prevent blockages
• Periodic filter replacement
• Connection integrity checks
• Operational monitoring (cooling performance, frost formation, compressor temperature)
• Professional servicing for comprehensive inspections

For irreparable failures, professional valve replacement involves:

1. Refrigerant recovery
2. Old valve removal
3. New valve installation (ensuring correct model/orientation)
4. Secure piping connections
5. System evacuation
6. Precise refrigerant recharge
7. Operational testing

Critical Notes: Match original valve specifications, verify installation direction, ensure leak-free connections, complete vacuuming, and maintain proper refrigerant charge levels.

As indispensable refrigeration components, expansion valves critically influence AC performance through precise refrigerant regulation. Understanding their operation, failure modes, and maintenance requirements enables optimized system performance and extended equipment lifespan.