TECUMSEH, DAIKIN, MATSUSHITA, HITACHI & TOSHIBA MODELS
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COMPREHENSIVE REFRIGERATION COMPRESSOR SPECIFICATIONS GUIDE: TECUMSEH, DAIKIN, MATSUSHITA, HITACHI & TOSHIBA MODELS
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Complete Compressor Specifications: 5 Major Brands Compared
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Technical specifications for Tecumseh, Daikin, Matsushita, Hitachi, and Toshiba compressors. Cooling capacity, displacement, voltage, power ratings, and applications.
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Understanding refrigeration compressor specifications is essential for proper HVAC system selection and maintenance. This comprehensive guide covers five major compressor brands—Tecumseh, Daikin, Matsushita, Hitachi, and Toshiba—with detailed technical data on cooling capacity, displacement, voltage requirements, and applications.
ARTICLE CONTENT
Understanding Refrigeration Compressor Specifications: A Complete Technical Guide
Refrigeration compressors form the backbone of modern cooling systems, converting electrical energy into mechanical work that circulates refrigerant through air conditioning and freezing applications. The choice between different compressor types and brands directly impacts system efficiency, reliability, and operational costs. This guide examines five leading manufacturers and their specific models, providing technical data essential for system designers, technicians, and facility managers.
SECTION 1: THE THREE MAIN COMPRESSOR ARCHITECTURES
1.1 Reciprocating (Piston) Compressors
Tecumseh Piston-Type Compressors operate using a linear piston mechanism that creates compression through reciprocating motion. The piston moves back and forth within a cylinder, drawing refrigerant vapor during the intake stroke and expelling it during the discharge stroke. This intermittent compression process makes reciprocating units ideal for applications with varying load conditions.
Key Technical Characteristics:
- Compression Method: Linear piston displacement with intake and discharge valve cycles
- Operating Range: Evaporating temperatures from −23.3°C to 12.8°C (−10°F to 55°F)
- Cooling Mechanism: External fan cooling standard for continuous operation
- Motor Type: PSC (Permanent Split Capacitor) with low start torque
- Displacement Range: 54–57 cc/revolution
- Refrigerant Compatibility: R22 and R407C (drop-in replacement available with minor modifications)
Tecumseh AW Series Specifications Table:
| Model | Power | Voltage | Cooling Capacity | Weight | Temp. Range |
|---|---|---|---|---|---|
| AW5524E | 2.5 HP | 220V | 20,000 BTU | 20 kg | −23°C to +13°C |
| AW5528EKGb | 2.5 HP | 220V | 20,000 BTU | 20 kg | −23°C to +13°C |
| AW5532EXG | 3 HP | 220V | 25,500 BTU | 20 kg | −23°C to +13°C |
| AW5532EXG | 3 HP | 380V | 26,500 BTU | 20 kg | −23°C to +13°C |
| AW5535EXG | 3 HP | 380V | 25,700 BTU | 20 kg | −23°C to +13°C |
| AV5538EXG | 4 HP | 380V | 27,300 BTU | 20 kg | −23°C to +13°C |
| AV5561EXG | 5 HP | 380V | 29,500 BTU | 20 kg | −23°C to +13°C |
Advantages of Reciprocating Compressors:
Piston compressors deliver exceptional reliability in applications experiencing frequent start-stop cycles. Their robust valve mechanisms tolerate liquid slugging (brief exposure to liquid refrigerant) better than scroll designs, making them preferred for systems with inadequate accumulator protection. The low start torque characteristic ensures smooth startup with minimal inrush current, reducing electrical strain on facility power systems.
Limitations and Considerations:
The intermittent compression cycle creates variable discharge pressure, producing higher vibration levels than scroll or rotary units. Tecumseh piston compressors typically require additional acoustic insulation in residential applications. The higher discharge temperature (frequently exceeding 90°C) demands effective cooling to prevent thermal overload protection activation during sustained operation.
1.2 Scroll Compressors
Daikin Scroll-Type Compressors employ two interleaving spiral-shaped elements—one stationary and one orbiting—to compress refrigerant in a continuous process. The orbiting scroll moves within the fixed scroll, progressively reducing the volume of pockets containing refrigerant gas, resulting in efficient, quiet compression.
Key Technical Characteristics:
- Compression Method: Continuous spiral pocket compression with minimal pressure fluctuation
- Moving Parts: Single orbiting scroll (dramatically fewer moving components than piston designs)
- Discharge Temperature: 15–25°C cooler than reciprocating units under identical conditions
- Vibration Level: 40–50% lower noise generation compared to piston designs
- Volumetric Efficiency: 89–94% across operating range
- COP (Coefficient of Performance): Typically 3.0–3.2 (3–18% higher than reciprocating at equivalent capacities)
Daikin JT Series Specifications Table:
| Model | Type | Power | Voltage | Cooling Capacity | Current | Displacement |
|---|---|---|---|---|---|---|
| JT90/220V | Scroll | 3 HP | 220V, 50Hz | 29,100 BTU | 16 A | 49.4 cc/rev |
| JT90/380V | Scroll | 3 HP | 380V, 50Hz | 29,200 BTU | 16 A | 49.4 cc/rev |
| JT95/220V | Scroll | 3 HP | 220V, 50Hz | 30,800 BTU | 16 A | 49.4 cc/rev |
| JT95/380V | Scroll | 3 HP | 380V, 50Hz | 31,400 BTU | 16 A | 49.4 cc/rev |
| JT125/220V | Scroll | 4 HP | 220V, 50Hz | 35,400 BTU | 16 A | 65.2 cc/rev |
| JT125/380V | Scroll | 4 HP | 380V, 50Hz | 40,600 BTU | 16 A | 65.2 cc/rev |
Performance Advantages:
Scroll compressors deliver consistent cooling capacity with minimal fluctuation, ideal for precision temperature control in commercial refrigeration and dehumidification applications. The continuous compression mechanism prevents the pressure spikes and valve shock common in reciprocating units, extending component lifespan significantly. Energy efficiency improves 5–12% compared to piston units at part-load operation, directly reducing operating costs in facilities with variable cooling demand.
Application Suitability:
Daikin scroll compressors excel in supermarket display cases, walk-in freezers, and packaged air conditioning units where energy consumption directly impacts profitability. The lower discharge temperature eliminates need for additional cooling infrastructure, simplifying system design and reducing material costs.
1.3 Rotary Compressors (Orbital and Roller Types)
Matsushita, Hitachi, and Toshiba Rotary-Type Compressors use rotating elements—either orbiting rollers or rotating vanes—to compress refrigerant in a continuous circular motion. Rotary designs achieve the highest cooling capacity per unit displacement among the three primary architectures.
Compression Mechanism Comparison:
Rotary vs. Scroll vs. Reciprocating Performance demonstrates distinct efficiency characteristics across operating conditions:
| Performance Metric | Reciprocating | Scroll | Rotary |
|---|---|---|---|
| Volumetric Efficiency | 75–82% | 89–94% | 88–92% |
| COP at Nominal Load | 2.8–3.0 | 3.0–3.2 | 2.9–3.1 |
| Discharge Temperature | 85–95°C | 65–75°C | 70–80°C |
| Noise Level (dB) | 78–82 | 72–75 | 73–78 |
| Vibration Index | High | Very Low | Low-Medium |
| Optimal Capacity Range | 15–25 kBTU | 8–35 kBTU | 8–24 kBTU |
| Part-Load Efficiency | Moderate | Excellent | Good |
| Continuous Operation | Requires cooling | Excellent | Excellent |
Research confirms rotary compressors deliver superior efficiency up to approximately 24,000 BTU/h capacity with alternative refrigerants like R407C and R410A. Above this threshold, scroll compressors demonstrate measurable efficiency advantages.
SECTION 2: MATSUSHITA ROTARY COMPRESSOR SPECIFICATIONS
Matsushita (Panasonic) manufactures rotary compressors for commercial and semi-commercial applications, featuring displacement-based capacity selection.
Technical Performance Data:
| Model | Displacement | Cooling Capacity | Power | Voltage | Amperage | Weight |
|---|---|---|---|---|---|---|
| 2P14C | 74.5 cc/rev | 25,500 BTU | — | 220V | 40 A | 40 kg |
| 2P17C | 92.6 cc/rev | 28,400 BTU | — | 220V | 40 A | 40 kg |
| 2K22C | 130.0 cc/rev | 44,400 BTU | — | 220V | 40 A | 40 kg |
| 2K32C | 177.4 cc/rev | 60,700 BTU | — | 220V | 40 A | 40 kg |
| 2V36S | 209.5 cc/rev | 71,400 BTU | — | 220V | 30 A | 30 kg |
| 2V42S | 245.7 cc/rev | 83,700 BTU | — | 220V | 30 A | 30 kg |
| 2V47W | 285.0 cc/rev | 97,200 BTU | — | 220V | 30 A | 30 kg |
Key Design Features:
Matsushita rotary units employ roller-type compression elements providing smooth, continuous pressure rise. The high displacement range (74.5–285 cc/revolution) allows system designers to select optimal compressor sizes for any cooling demand from small commercial units to large industrial installations.
Efficiency Characteristics:
Performance testing demonstrates 92–94% volumetric efficiency across standard operating ranges. The displacement-to-displacement comparison shows Matsushita models deliver consistent cooling per cc/rev, enabling accurate system capacity calculations from displacement data alone.
SECTION 3: HITACHI ROTARY COMPRESSOR SPECIFICATIONS
Hitachi rotary compressors represent Japanese engineering excellence, widely deployed in Asian HVAC markets with proven long-term reliability.
Hitachi G Series (General Purpose):
| Model | Displacement | Cooling Capacity | Power | Voltage | Amperage |
|---|---|---|---|---|---|
| G533 | 33.8 cc/rev | 9,036 BTU | — | 220V | 40 A |
| G533 | — | 12,518 BTU (1 TON) | — | 220V | 40 A |
Hitachi SH Series (Standard Heating/Cooling):
| Model | Displacement | Cooling Capacity | Power | Voltage | Amperage |
|---|---|---|---|---|---|
| SH833 | 51.8 cc/rev | 12,518 BTU (1 TON) | — | 220V | 40 A |
| SHY33 | 41.7 cc/rev | 17,612 BTU | — | 220V | 40 A |
| SHW33 | 35.6 cc/rev | 20,425 BTU | — | 220V | 30 A |
| SHX33 | 33.6 cc/rev | 19,198 BTU | — | 220V | 30 A |
| SHV33 | 41.7 cc/rev | 24,211 BTU | — | 220V | 30 A |
| SHU33 | — | 27,689 BTU (2 TON) | — | 220V | 30 A |
Hitachi Refrigeration Tons Standard:
The “TON” designation historically represents refrigeration capacity equivalent to melting one metric ton of ice in 24 hours:
- 1 Refrigeration Ton ≈ 3.517 kW ≈ 12,000 BTU/h
Conversion Reference for Hitachi Models:
| Tons | Approximate BTU/h | Approximate Watts |
|---|---|---|
| 1 TON | 12,000 BTU | 3,517 W |
| 1.5 TON | 18,000 BTU | 5,275 W |
| 2 TON | 24,000 BTU | 7,033 W |
| 2.5 TON | 30,000 BTU | 8,792 W |
| 3 TON | 36,000 BTU | 10,550 W |
Hitachi Market Position:
Hitachi compressors command premium pricing justified by superior manufacturing tolerances and extended warranty provisions. The displacement-rated design enables technicians to verify model accuracy and estimate remaining useful life through displacement measurement alone.
SECTION 4: TOSHIBA ROTARY COMPRESSOR SPECIFICATIONS
Toshiba rotary compressors dominate Southeast Asian refrigeration markets, featuring robust construction and wide displacement availability.
Toshiba PH Series (220V Single-Phase):
| Model | Displacement | Cooling Capacity | Power | Voltage | Amperage |
|---|---|---|---|---|---|
| PH165X1C | 16.5 cc/rev | 15,828 BTU | — | 220V | 40 A |
| PH195X2C | 19.8 cc/rev | 19,558 BTU | — | 220V | 40 A |
| PH225X2C | 22.4 cc/rev | 21,348 BTU | — | 220V | 40 A |
| PH260X2C | 25.8 cc/rev | 26,688 BTU | — | 220V | 40 A |
| PH290X2C | 28.9 cc/rev | 29,372 BTU | — | 220V | 40 A |
| PH295X2C | 29.2 cc/rev | 29,688 BTU | — | 220V | 40 A |
| PH310X2C | 30.6 cc/rev | 31,488 BTU | — | 220V | 30 A |
| PH330X2C | 32.6 cc/rev | 33,088 BTU | — | 220V | 30 A |
| PH360X3C | 35.5 cc/rev | 36,192 BTU | — | 220V | 30 A |
| PH420X3C | 41.5 cc/rev | 42,816 BTU | — | 220V | 30 A |
| PH440X3C | 43.5 cc/rev | 44,448 BTU | — | 220V | 30 A |
Toshiba Technical Characteristics:
The progressive displacement series (PH165 → PH440) provides system designers with precise capacity matching. Each increment adds approximately 3.0–4.5 cc/rev displacement, corresponding to 2,000–4,000 BTU capacity increases, enabling optimal system configuration for diverse applications.
Performance Efficiency Data:
Toshiba rotary compressors maintain 91–93% volumetric efficiency at ARI standard rating conditions (evaporating −23.3°C, condensing 54°C). Continuous operation reliability testing demonstrates 40,000+ hour MTBF (Mean Time Between Failures) under normal maintenance protocols.
SECTION 5: MATSUSHITA ROTARY UNIT COMPRESSOR SPECIFICATIONS
Matsushita Rotary Unit compressors represent the company’s premium product line, featuring enhanced efficiency and expanded capacity range for large-scale installations.
Technical Specifications:
| Model | Displacement | Cooling Capacity | Power | Voltage | Amperage |
|---|---|---|---|---|---|
| 2P514D | 51.4 cc/rev | 17,548 BTU | — | 220V | 40 A |
| 2K5210D5 | 109.0 cc/rev | 37,200 BTU | — | 220V | 40 A |
| 2K5324D5 | 180.0 cc/rev | 61,272 BTU | — | 220V | 40 A |
| 2K5324D5 | 180.0 cc/rev | 43,872 BTU | — | 220V | 40 A |
| 2K5314D | 177.4 cc/rev | 60,192 BTU | — | 220V | 40 A |
| 2J5350D | 209.5 cc/rev | 31,632 BTU | — | 220V | 30 A |
| 2J5438D | 265.4 cc/rev | 45,360 BTU | — | 220V | 30 A |
Premium Features:
Matsushita Rotary Units incorporate enhanced oil circulation systems ensuring superior bearing lubrication under continuous operation. The optimized valve ports reduce pressure drop during refrigerant flow, achieving 3–5% efficiency improvement compared to standard Matsushita rotary compressors.
SECTION 6: COMPREHENSIVE COMPRESSOR COMPARISON & SELECTION GUIDELINES
6.1 Energy Efficiency Comparison
Coefficient of Performance (COP) Analysis across compressor types:
| Cooling Capacity Range | Most Efficient Type | Typical COP | Comments |
|---|---|---|---|
| 8,000–12,000 BTU | Rotary | 3.0–3.1 | Rotary/scroll equivalent; rotary preferred if cost-effective |
| 12,000–18,000 BTU | Scroll | 3.1–3.3 | Scroll begins efficiency advantage |
| 18,000–24,000 BTU | Scroll | 3.2–3.4 | Scroll provides 5–8% higher COP than rotary |
| 24,000–35,000 BTU | Scroll | 3.3–3.5 | Scroll optimal; rotary less suitable |
| Variable Load/Intermittent | Reciprocating | 2.8–3.0 | Piston preferred for duty-cycle tolerance |
| High-Reliability Industrial | Reciprocating | 2.9–3.1 | Piston superior for extreme conditions |
Engineering Recommendation: Select compressor types based on primary operational profile:
- Continuous steady-state cooling → Scroll (Daikin) for maximum efficiency
- Variable load/startup-shutdown cycles → Reciprocating (Tecumseh) for durability
- Small commercial 12–24 kBTU range → Rotary (Matsushita/Hitachi/Toshiba) for cost-effective balance
6.2 Capacity Matching Methodology
Displacement-to-Cooling Capacity Conversion:
The relationship between mechanical displacement and actual cooling capacity varies by compressor type and refrigerant:
Approximate Rule of Thumb (R22 at Standard Rating Conditions):
- Reciprocating: 130–150 BTU per cc/rev displacement
- Scroll: 110–140 BTU per cc/rev displacement
- Rotary: 80–120 BTU per cc/rev displacement
Example Application Calculation:
Scenario: Design a 25,000 BTU cooling system.
| Compressor Type | Required Displacement | Model Selection | Voltage | Weight |
|---|---|---|---|---|
| Reciprocating | ~170 cc/rev | Tecumseh AW5532EXG | 220V | 20 kg |
| Scroll | ~210 cc/rev | Daikin JT95 | 220V | — |
| Rotary | ~230 cc/rev | Toshiba PH290X2C | 220V | — |
SECTION 7: TEMPERATURE RANGE CLASSIFICATIONS & APPLICATIONS
7.1 Evaporating Temperature Ranges
Compressor specification sheets consistently reference evaporating temperature ranges determining suitability for specific applications:
Standard Classification System:
| Evaporating Range | Designation | Applications |
|---|---|---|
| −30°C to −23°C | LBP (Low Back Pressure) | Deep freezing, blast freezing, frozen food storage |
| −23°C to −10°C | MBP (Medium Back Pressure) | Standard refrigeration, commercial freezers, ice cream display |
| −10°C to +5°C | HBP (High Back Pressure) | Fresh food storage, chiller cabinets, air conditioning |
| +5°C to +12°C | XHBP (Extra High Back Pressure) | Air conditioning, dehumidification, comfort cooling |
Technical Significance:
Evaporating temperature determines refrigerant pressure at the compressor suction port. Lower evaporating temperatures produce lower suction pressures, requiring compressors with higher pressure ratios to achieve condensing pressure. The Tecumseh piston compressors (evaporating −23.3°C to +12.8°C) demonstrate design flexibility across moderate temperature ranges.
7.2 Motor Torque Characteristics
Low Start Torque (LST) versus High Start Torque (HST) affects electrical system compatibility:
| Torque Type | Motor Current at Startup | Suitable Applications | Electrical Requirement |
|---|---|---|---|
| LST | 3–5 × FLA (Full Load Amperage) | Standard power-supplied facilities | 15–20 A circuit breaker minimum |
| HST | 5–8 × FLA | Low-voltage supply situations | 25–30 A circuit breaker minimum |
Consideration: Tecumseh reciprocating compressors employ PSC (Permanent Split Capacitor) motors with LST design, simplifying electrical installation and reducing inrush current stress on building power infrastructure.
SECTION 8: REFRIGERANT SELECTION & SYSTEM INTEGRATION
8.1 R22 versus Alternative Refrigerants
R22 (Chlorodifluoromethane) remains the industry standard for existing equipment, but progressive phase-out mandates understanding alternative refrigerant performance:
Refrigerant Compatibility Matrix:
| Aspect | R22 (CFC) | R407C (HFC Blend) | R410A (HFC Blend) | R290 (Propane) |
|---|---|---|---|---|
| Ozone Depletion | High (0.055) | Zero | Zero | Zero |
| GWP (Global Warming Potential) | 1,810 | 1,774 | 2,088 | 3 |
| Pressure (Condensing 54°C) | 19.2 bar | 20.8 bar | 28.6 bar | 18.1 bar |
| Molecular Weight | 120.9 g/mol | 86.2 g/mol | 72.0 g/mol | 44.1 g/mol |
| Density (Liquid 25°C) | 1.194 g/cm³ | 1.065 g/cm³ | 0.766 g/cm³ | 0.58 g/cm³ |
| Viscosity (Oil Compatibility) | Mineral oil | Mineral/POE oil | Ester (POE) oil | Ester (POE) oil |
| Drop-in Replacement | Reference | Limited (capacity −5–10%) | Not drop-in | Safety concern |
System Design Implications:
R407C retrofitting requires sealed system replacement, oil flush, and system evacuation to <500 microns vacuum. Capacity typically decreases 5–10% compared to R22, necessitating larger compressor displacement or higher-capacity alternative models.
R410A systems demand higher-pressure rated components, including compressors, condenser coils, and expansion devices. Existing R22 system components are mechanically incompatible with R410A pressures.
SECTION 9: PRACTICAL MAINTENANCE & TROUBLESHOOTING GUIDANCE
9.1 Compressor Oil Charge Specifications
Correct refrigerant oil volume directly affects bearing lubrication and heat transfer efficiency:
Oil Charge Capacity (Reference Values):
| Compressor Type/Model | Oil Charge Volume | Oil Type | Purpose |
|---|---|---|---|
| Tecumseh AW5532EXG | 1,100–1,300 mL | Mineral (ISO VG 32) | Bearing/piston lubrication |
| Daikin JT90/JT95 | 1,800–2,100 mL | Mineral (ISO VG 32) | Bearing/scroll pocket lubrication |
| Matsushita 2P17C | 2,200–2,400 mL | Mineral (ISO VG 32) | Bearing/roller pocket lubrication |
| Hitachi SHY33/SHV33 | 1,600–1,900 mL | Mineral (ISO VG 32) | Bearing/vane lubrication |
| Toshiba PH295X2C | 1,200–1,500 mL | Mineral (ISO VG 32) | Bearing/roller pocket lubrication |
Critical Maintenance Notice: Under-lubrication causes bearing wear within 500–1,000 operating hours. Over-lubrication reduces cooling capacity 2–5% and increases discharge temperature 3–8°C.
9.2 Condensing Temperature Management
Discharge Temperature Calculation from condensing conditions:
Formula: Discharge Temperature (°C) = Condensing Temperature + Superheat Rise
Typical Superheat Rise Values:
- Reciprocating (Tecumseh): 12–18°C above condensing temperature
- Scroll (Daikin): 8–14°C above condensing temperature
- Rotary (Matsushita/Hitachi/Toshiba): 10–16°C above condensing temperature
Example: Tecumseh AW5532EXG operating at 54°C condensing temperature:
- Expected discharge temperature: 54°C + 15°C = 69°C (normal)
- Alarm threshold: 95°C (overheating protection activates)
Operating Margin: 26°C buffer between normal operation and thermal shutdown provides safety margin for transient load spikes.
SECTION 10: ADVANCED SELECTION CRITERIA FOR HVAC PROFESSIONALS
10.1 Volumetric Efficiency & Capacity Degradation
Volumetric efficiency decreases with compressor age due to:
- Valve wear (reciprocating) → increased leakage
- Scroll clearance growth → reduced effective compression volume
- Bearing wear → increased friction losses
- Motor winding degradation → reduced torque output
Expected Service Life Performance:
| Compressor Type | Rated Hours | Efficiency at 5,000 hrs | Efficiency at 10,000 hrs | Typical Maintenance Interval |
|---|---|---|---|---|
| Reciprocating | 10,000–15,000 | 95–98% | 88–92% | 2,500 hours or annually |
| Scroll | 15,000–20,000 | 96–99% | 90–95% | 5,000 hours or 18 months |
| Rotary | 12,000–18,000 | 94–97% | 88–91% | 3,000 hours or annually |
10.2 Noise and Vibration Characteristics
Acoustic Performance Ranking:
- Scroll (Daikin): 72–75 dB @ 1 meter — smoothest operation
- Rotary (Matsushita/Hitachi/Toshiba): 73–78 dB @ 1 meter — moderate vibration
- Reciprocating (Tecumseh): 78–82 dB @ 1 meter — highest vibration and noise
Installation Implications: Residential applications require scroll or rotary compressors with vibration isolators and sound barriers. Commercial and industrial installations typically accept reciprocating compressor noise with standard mounting.
SECTION 11: CAPACITY CONVERSION REFERENCE TABLE
Quick Reference: Converting Between Common Cooling Capacity Units
| BTU/h | Watts (W) | Kilowatts (kW) | Refrigeration Tons (TR) | kcal/h |
|---|---|---|---|---|
| 8,500 | 2,491 | 2.49 | 0.71 | 2,141 |
| 10,236 | 3,000 | 3.00 | 0.85 | 2,580 |
| 12,000 | 3,517 | 3.52 | 1.00 | 3,024 |
| 15,000 | 4,396 | 4.40 | 1.25 | 3,780 |
| 18,000 | 5,275 | 5.28 | 1.50 | 4,536 |
| 20,425 | 5,987 | 5.99 | 1.68 | 5,152 |
| 24,000 | 7,033 | 7.03 | 2.00 | 6,048 |
| 25,500 | 7,472 | 7.47 | 2.14 | 6,425 |
| 29,100 | 8,526 | 8.53 | 2.42 | 7,344 |
| 30,800 | 9,026 | 9.03 | 2.56 | 7,777 |
| 36,000 | 10,550 | 10.55 | 3.00 | 9,072 |
Conversion Formula: 1 BTU/h = 0.293 Watts
SECTION 12: FIELD EXPERT RECOMMENDATIONS & BEST PRACTICES
12.1 Installation Best Practices
Compressor Positioning & Orientation:
- Mount horizontally or slightly inclined (5–10°) to ensure oil return during operation
- Avoid vertical mounting unless designed for that orientation
- Provide minimum 30 cm clearance for air circulation around external cooling fins
- Ensure suction line elevation permits oil return (minimum 1% pitch toward compressor)
Electrical Connection Standards:
- Use wire gauge rated for 125% of compressor full-load amperage
- Install dedicated 20-ampere circuit breaker with overload protection
- Confirm voltage tolerance: ±10% of nameplate rating (e.g., 220V ±22V)
- Verify motor capacitor rating matches nameplate (typically 25–50 µF for PSC motors)
12.2 Commissioning Checklist
Before putting refrigeration compressors into service:
Pre-startup Verification:
- Â Vacuum system to <500 microns (absolute) using deep-vacuum pump
- Â Charge system with specified refrigerant quantity (liquid measure from cylinder scale, never by pressure)
-  Verify oil level within sight glass (60–80% full)
-  Confirm suction line superheat 5–15°C (use calibrated thermometer + pressure gauge)
- Â Measure discharge line temperature (should align with predicted values from Section 9.2)
-  Verify compressor current draw within nameplate amperage ±10%
- Â Monitor system operation for 30 minutes (listen for unusual noise, vibration)
Capacity Verification Test:
Actual cooling capacity can be verified through calorimetric measurement:
Formula: Q (BTU/h) = Mass flow rate (lb/min) × 60 × Specific heat difference (BTU/lb)
Alternatively, use superheat/subcooling method to confirm proper system charge and compressor operation.
SECTION 13: COMMON FAILURE MODES & DIAGNOSTIC APPROACH
13.1 Symptom-to-Root-Cause Diagnostic Table
| Symptom | Likely Causes | Diagnostic Method | Corrective Action |
|---|---|---|---|
| Low cooling capacity (5–15% below spec) | Oil overcharge, dirty evaporator coil, undercharge, expansion device restriction | Superheat measurement, oil level inspection, coil cleaning, subcooling measurement | Restore oil to correct level, clean coil, adjust refrigerant charge, replace expansion device if needed |
| High discharge temperature (>95°C) | Condenser fouling, excessive condensing temperature, undercharge, oil starvation | Discharge temperature measurement, condensing temperature check, refrigerant charge verification | Clean condenser coils, verify ambient conditions, add refrigerant if undercharged, check oil level |
| Frequent compressor shutdown | Overload protection activation from electrical overload or thermal stress | Monitor discharge temperature during operation, measure electrical current draw | Improve condenser cooling, reduce system load, verify electrical supply voltage, check motor condition |
| Excessive noise/vibration | Mechanical wear (bearing clearance), piston/scroll damage, loose mounting, liquid slugging | Visual inspection of compressor exterior, vibration measurement, listen for grinding noise | Replace compressor if bearing wear confirmed, install proper oil separator and accumulator, improve mounting |
| Liquid refrigerant return to compressor | Insufficient accumulator capacity, poor piping design, low evaporator temperature | Inspect piping configuration, check accumulator capacity, monitor suction temperature | Install larger accumulator, redesign suction line with proper pitch, adjust thermostat setpoint |
13.2 Oil Acid Number (TAN) Degradation
Oil quality directly impacts compressor lifespan:
| Acid Number (mg KOH/g) | Oil Condition | Recommended Action |
|---|---|---|
| <0.5 | Fresh, acceptable | Continue normal operation; test annually |
| 0.5–1.0 | Slightly oxidized | Monitor closely; plan oil change within 1–2 years |
| 1.0–2.0 | Moderately oxidized | Schedule oil change within 6 months |
| >2.0 | Severely degraded | Replace oil immediately; may indicate moisture ingress or compressor overheating |
Oil change intervals vary by operating conditions:
- Normal ambient (15–35°C): Every 2–3 years
- High ambient (>35°C): Every 12–18 months
- High-load continuous operation: Every 6–12 months
- Presence of moisture: Immediate replacement required
SECTION 14: TECHNICAL SPECIFICATIONS SUMMARY TABLE
One-Page Reference Comparing All Compressor Models Covered
| Brand | Model | Type | Power | Voltage | Cooling Capacity | Displacement | Weight | Key Feature |
|---|---|---|---|---|---|---|---|---|
| Tecumseh | AW5532EXG | Piston | 3 HP | 220V | 25,500 BTU | 54 cc/rev | 20 kg | LST, fan-cooled, variable load capable |
| Tecumseh | AV5538EXG | Piston | 4 HP | 380V | 27,300 BTU | — | 20 kg | Higher capacity for industrial |
| Daikin | JT95/220V | Scroll | 3 HP | 220V | 30,800 BTU | 49.4 cc/rev | — | Highest efficiency, lowest noise |
| Daikin | JT125/380V | Scroll | 4 HP | 380V | 40,600 BTU | 65.2 cc/rev | — | Three-phase, large capacity |
| Matsushita | 2P17C | Rotary | — | 220V | 28,400 BTU | 92.6 cc/rev | 40 kg | Compact, cost-effective |
| Matsushita | 2K32C | Rotary | — | 220V | 60,700 BTU | 177.4 cc/rev | 40 kg | Extra-large capacity option |
| Hitachi | SHY33 | Rotary | — | 220V | 17,612 BTU | 41.7 cc/rev | 30 A | Premium, high reliability |
| Hitachi | SHV33 | Rotary | — | 220V | 24,211 BTU | 41.7 cc/rev | 30 A | Enhanced efficiency variant |
| Toshiba | PH225X2C | Rotary | — | 220V | 21,348 BTU | 22.4 cc/rev | 40 A | Wide availability, budget option |
| Toshiba | PH290X2C | Rotary | — | 220V | 29,372 BTU | 28.9 cc/rev | 40 A | Mid-range capacity, popular |
| Toshiba | PH360X3C | Rotary | — | 220V | 36,192 BTU | 35.5 cc/rev | 30 A | Large single-phase application |
SECTION 15: ENVIRONMENTAL CONSIDERATIONS & FUTURE TRENDS
15.1 Refrigerant Phase-Out Timeline
The Montreal Protocol and subsequent amendments mandate progressive refrigerant phase-out:
R22 Timeline:
- 2020: Developed nations complete R22 production phase-out
- 2025: Developing nations must reduce R22 consumption by 65%
- 2030: Developing nations must achieve 90% reduction
- 2040: Complete phase-out (limited servicing stocks allowed)
Implications for Technicians:
- Existing R22 systems continue operating with recycled/reclaimed refrigerant
- New compressor selection must accommodate alternative refrigerants
- Oil compatibility changes when transitioning to R407C, R410A, or propane-based alternatives
- System pressure ratings increase with higher-pressure refrigerants
15.2 Emerging High-Efficiency Alternatives
Variable-frequency-drive (VFD) compressors enable capacity modulation, improving part-load efficiency by 20–30% compared to fixed-displacement units.
Magnetic-bearing compressors eliminate friction losses, achieving COP values above 4.5 in laboratory conditions, though cost remains prohibitive for standard HVAC applications.
SECTION 16: PURCHASING GUIDANCE & SUPPLIER CONSIDERATIONS
16.1 Specification Verification Checklist
When ordering replacement compressors, confirm:
-  Model number matches exactly (including letter suffixes indicating refrigerant/voltage/torque type)
-  Cooling capacity specification in same units (BTU/h, kW, or TR) as system design
-  Voltage and phase (1PH 220V, 3PH 380V, etc.) match facility electrical supply
-  Refrigerant type (R22, R407C, etc.) compatible with existing system or justified retrofit plan
-  Discharge port connections (flange size, thread type, O-ring groove style) match existing tubing
-  Oil type and quantity specified in compressor documentation
-  Warranty period and coverage terms documented (typically 12–24 months)
-  Manufacturer certification (CE-marked for EU compliance, or equivalent regional compliance)
16.2 Common Model Number Decoding
Tecumseh Example: AW5532EXG
- AÂ = Hermetic (sealed)
- WÂ = Standard enclosure
- 55Â = Displacement series (550 cc/rev class)
- 32Â = Specific displacement (approximately)
- EXGÂ = Extended application, R407C compatible, group G motor torque
Daikin Example: JT95BCBV1L
- JTÂ = Scroll compressor line
- 95Â = Approximate capacity (95 cc displacement, ~30 kBTU)
- BCÂ = Bearing and oil type (BC = standard bearing)
- BVÂ = Valve configuration
- 1LÂ = 220V/50Hz single-phase variant
CONCLUSION: SELECTING THE RIGHT COMPRESSOR FOR YOUR APPLICATION
The refrigeration compressor represents the highest-cost and most critical component in any HVAC or cooling system. Understanding the technical distinctions between reciprocating (piston), scroll, and rotary architectures enables facility managers and HVAC professionals to make informed decisions balancing efficiency, reliability, and cost.
Key Takeaways:
✓ Scroll compressors (Daikin JT series) deliver superior energy efficiency and quiet operation, ideal for continuous applications in temperature-controlled environments.
✓ Reciprocating piston compressors (Tecumseh AW/AV series) provide unmatched reliability for systems experiencing variable load cycles and startup-shutdown events.
✓ Rotary compressors (Matsushita, Hitachi, Toshiba) balance efficiency and cost-effectiveness, particularly valuable in emerging markets and small-to-medium capacity applications.
✓ Displacement-based selection enables precise capacity matching by dividing required cooling capacity (BTU) by manufacturer efficiency factor.
✓ Refrigerant compatibility must drive compressor selection, particularly given R22 phase-out and growing adoption of R407C and R410A alternatives.
✓ Proper oil charge, superheat adjustment, and commissioning procedures determine whether a compressor achieves nameplate capacity and design lifespan.
For facility planners and cooling system designers, detailed specification knowledge transforms compressor selection from guesswork into precision engineering, directly improving system performance, reducing energy consumption, and extending equipment lifespan.
