PT Calculator

Enter a temperature or a pressure for any refrigerant in the dataset; get the corresponding saturation value, with bubble/dew handling for zeotropic blends and ten-plus worked examples covering the full range of HVAC service scenarios.

What the PT calculator actually computes

A PT calculator converts between refrigerant saturation pressure and saturation temperature at thermodynamic equilibrium. Pick a temperature, get the saturation pressure; pick a pressure, get the saturation temperature.

The math is direct lookup against the refrigerant's PT chart, interpolated linearly between the 1°F data points in the underlying dataset. The relationship is fundamental to vapor-compression refrigeration. Any point where liquid and vapor coexist — broadly, the evaporator and condenser — sits on the saturation curve.

Four representative refrigerants on a single PT chart, showing how saturation pressure rises with temperature. Source: CoolProp 7.2.0 saturation data, plotted over the −40°F to 130°F service range.

One thermodynamic relationship powers the whole tool

Every superheat measurement, every subcooling check, every charging procedure, and every retrofit pressure comparison traces back to the underlying PT lookup. The calculator on this page does the lookup; the worked examples below show how to apply it across the major HVAC scenarios.

Pure refrigerants vs zeotropic blends — why bubble and dew matter

Pure refrigerants (R-22, R-32, R-134a, R-744) have a single saturation curve — at any pressure there is one saturation temperature. Azeotropic blends (R-507A, R-500, R-502) behave the same way because their component proportions are engineered for zero-glide behavior.

Zeotropic blends (R-407C, R-454C, R-455A, R-448A, R-449A) have two saturation curves at any pressure: bubble, where the first vapor forms when heating the liquid, and dew, where the last liquid disappears when condensing the vapor. The temperature difference between bubble and dew at the same pressure is the temperature glide.

Glide visualization for R-407C across a typical residential evaporator coil at 40°F bubble. Source: CoolProp 7.2.0 saturation data.

For service measurement, the curve selection matters. Suction-line superheat uses the dew temperature at suction pressure as the saturation reference; liquid-line subcooling uses the bubble temperature at discharge pressure. Wrong-curve selection introduces measurement error equal to the glide.

Temperature glide across common HVAC blends, measured as bubble-minus-dew at 0°C (CoolProp 7.2.0 dataset value). Pure refrigerants and azeotropes have zero glide and are omitted.

Real service problems solved with the PT chart

Ten field scenarios spanning residential AC, commercial refrigeration, chillers, mobile AC, transcritical CO2, and heat pumps. Each shows what gets measured at the manifold, the PT chart lookups that convert pressures to saturation temperatures, the derived superheat / subcooling values, and a verdict on what to do next.

Service problemR-410A

Verifying R-410A charge on a 95°F day

Scenario · 3-ton residential R-410A central AC, 95°F outdoor ambient, 75°F indoor return air, TXV metering device. The system has been running 20 minutes at steady state and you want to confirm charge before signing off.

Measured at the manifold

Suction P

130 PSIG

Suction line

60°F

Discharge P

380 PSIG

Liquid line

100°F

PT chart lookup (R-410A)

130 PSIG45°F satevaporator saturation

380 PSIG111°F satcondenser saturation

Derived

Superheat = 60°F − 45°F = 15°Fin target 8-15°F

Subcooling = 111°F − 100°F = 11°Fin target 8-12°F

OK · Properly charged — no service action

Superheat and subcooling both sit inside the standard target ranges; suction and discharge match what we expect at 95°F design ambient. Sign off and move on.

Service problemR-410A

Spotting an R-410A undercharge after a leak repair

Scenario · Same 3-ton residential R-410A system, just back from a leak repair at the evaporator. You suspect the recharge wasn't complete and want to confirm before the customer calls back when the weather warms up.

Measured at the manifold

Suction P

100 PSIG

Suction line

65°F

Discharge P

320 PSIG

Liquid line

105°F

PT chart lookup (R-410A)

100 PSIG31°F satevaporator saturation

320 PSIG99°F satcondenser saturation

Derived

Superheat = 65°F − 31°F = 34°Fhigh — should be 8-15°F

Subcooling = 99°F − 105°F = −6°Fnegative — flash gas in liquid line

Action required · Classic undercharge fingerprint

Negative subcooling means vapor is reaching the metering device; high superheat means the evaporator is starving for liquid. Both lower-than-spec pressures and these derived values point to one cause: insufficient refrigerant in the system.

Fix

Confirm the leak is fully repaired (EPA Section 608 requires this before adding refrigerant), then charge by weight to nameplate using a recovery/charging scale. Re-test superheat and subcooling at steady state to confirm the fix.

Service problemR-410A

Catching an R-410A overcharge from a prior service add

Scenario · Same 3-ton residential R-410A system. A previous tech topped off by gauge feel rather than by weight. The compressor is running noisy and the customer is reporting higher power bills.

Measured at the manifold

Suction P

160 PSIG

Suction line

55°F

Discharge P

480 PSIG

Liquid line

90°F

PT chart lookup (R-410A)

160 PSIG55°F satevaporator saturation

480 PSIG130°F satcondenser saturation

Derived

Superheat = 55°F − 55°F = 0°Fzero — slugging risk to compressor

Subcooling = 130°F − 90°F = 40°Fvery high — excess liquid in condenser

Action required · Overcharge — liquid is reaching the compressor

Zero superheat with 40°F subcooling is the classic overcharge fingerprint. Excess refrigerant backs up in the condenser (high subcooling) and saturated liquid reaches the compressor suction (zero superheat); continued operation risks valve damage or hydraulic lock.

Fix

Recover refrigerant in 1 oz increments, re-testing superheat and subcooling after each step. Stop when superheat reaches 8-15°F and subcooling reaches 8-12°F.

Service problemR-454C (zeotropic, ~14°F glide)

Charging a wide-glide R-454C walk-in freezer

Scenario · R-454C walk-in freezer, -20°F target evaporator temperature, 95°F ambient. R-454C has roughly 14°F glide so curve selection matters: dew at suction for superheat, bubble at discharge for subcooling.

Measured at the manifold

Suction P

7 PSIG

Suction line

5°F

Discharge P

200 PSIG

Liquid line

95°F

PT chart lookup (R-454C — dual curves)

7 PSIG dew−20°F satevap outlet — use for superheat

7 PSIG bubble−34°F satevap inlet — reference only

200 PSIG bubble88°F satcond outlet — use for subcooling

200 PSIG dew74°F satcond inlet — reference only

Derived

Superheat (dew) = 5°F − (−20°F) = 25°Fhigh end of 10-20°F target

Subcooling check: 95°F liquid vs 88°F bubble = −7°Fliquid warmer than saturation — no subcooling

Action required · Insufficient subcooling — condenser-side issue

Liquid line warmer than the bubble at discharge means the condenser is not subcooling — likely undercharge or restricted condenser airflow. Using the wrong (bubble) curve for superheat would have computed 39°F instead of the actual 25°F, a 14°F error equal to the glide that would drive wrong charging decisions.

Fix

Verify condenser fan operation, clean the coil, then check refrigerant charge by weight. For zeotropic blends, always confirm curve selection in PT chart software: dew for suction-side superheat, bubble for discharge-side subcooling.

Service problemR-22 → R-407C retrofit

Pressure-envelope check for an R-22 to R-407C retrofit

Scenario · Existing R-22 residential AC under consideration for R-407C retrofit. Customer wants to know: will the existing manifold gauges, hoses, and line set handle R-407C, or does the equipment need replacement?

PT chart comparison (PSIG)

Refrigerant	40°F	70°F	95°F	Δ vs R-22
R-22 (pure)	69	121	181	baseline
R-407C bubble	80	141	215	+16-19%
R-407C dew	63	117	180	≈ R-22

Result · Compatible retrofit — standard procedure applies

R-407C bubble runs 16-19% above R-22; dew is essentially equal. Standard 500 PSI manifold gauges handle both refrigerants, and the difference matters mainly for service measurement: dew curve for superheat, bubble curve for subcooling on R-407C (R-22 has a single curve).

Fix

Standard retrofit procedure: recover R-22, drain mineral oil and replace with POE, swap the filter-drier, evacuate to 500 microns, then charge R-407C by weight to approximately 90% of the R-22 nameplate. Verify superheat and subcooling at steady state after recharge.

Service problemR-32 vs R-410A

Will R-410A service tools handle a new R-32 system?

Scenario · A homeowner is replacing an R-410A condenser with a new R-32 system. The field tech asks the practical question: do I need new manifold gauges, hoses, recovery cylinders for R-32, or can my existing R-410A gear stay?

PT chart comparison (PSIG)

Refrigerant	40°F	70°F	95°F	Δ vs R-410A
R-410A (near-azeotrope)	119	202	278	baseline
R-32 (pure)	124	206	296	+4-6%

Result · Yes — R-410A tools handle R-32 without modification

Pressure delta is only 4-6% across the residential operating range, well inside the safety margin of R-410A-rated equipment (800 PSI gauges, hoses, recovery cylinders). The design changes for R-32 are flammability-related (A2L sealed motors, charge limits), not pressure ratings.

Fix

Use existing R-410A service tools as-is. For the install, confirm indoor equipment is A2L-rated, the room volume meets the IEC 60335-2-40 charge limit table for the new charge size, and the existing line set is rated for R-32 service.

Service problemR-134a

Diagnosing a struggling R-134a centrifugal chiller

Scenario · Water-cooled R-134a centrifugal chiller. Operator reports the chiller has trouble making its 45°F leaving chilled water setpoint despite 85°F entering condenser water. You take manifold and liquid line readings.

Measured

Suction P

38 PSIG

Discharge P

152 PSIG

Liquid line

95°F

Leaving cond H₂O

95°F

PT chart lookup (R-134a)

38 PSIG47°F satevaporator saturation

152 PSIG113°F satcondenser saturation

Derived approach values

Evap approach = 47°F − 45°F = 2°Ftarget 2-5°F

Cond approach = 113°F − 95°F = 18°Fhigh — should be 5-10°F water-cooled

Subcooling = 113°F − 95°F = 18°Fhigh — consistent with cond approach

Action required · Condenser-side bottleneck

High condenser approach with high subcooling points to fouled condenser tubes (heat-transfer fouling raises condenser temperature for the same heat rejection) or low condenser water flow. Evaporator side looks fine, so the chiller capacity bottleneck is high-side heat rejection.

Fix

Inspect condenser tube cleanliness — schedule a brush-and-flush if fouled. Verify condenser water pump flow against the chiller's nameplate; check for bypass valves stuck open or strainer blockage upstream.

Service problemR-1234yf

Hot-day R-1234yf mobile AC verification

Scenario · 2020+ model year vehicle with R-1234yf MAC system. 100°F ambient, AC at max cooling, vehicle stationary in a parking lot. Customer says the cabin doesn't get cold enough; you hook up MAC manifold gauges.

Measured at MAC service ports

Low side

35 PSIG

High side

235 PSIG

Ambient

100°F

Vehicle state

Stationary

PT chart lookup (R-1234yf)

35 PSIG39°F satevaporator saturation

235 PSIG136°F satcondenser saturation

Interpretation

Cabin air ≈ evap sat + 1-3°F ≈ 40°Fappropriate cabin cooling

Cond above ambient = 136°F − 100°F = 36°Ftypical stationary vehicle

OK · Normal hot-day stationary MAC operation

Pressures and saturation temperatures fit typical hot-ambient stationary conditions. R-1234yf was engineered to preserve R-134a's pressure envelope (R-134a at 35 PSIG = 41°F; at 235 PSIG = 144°F), so existing MAC service procedures and equipment work without modification.

Fix

If the customer wants more cabin cooling at idle, advise that road speed (more airflow across the condenser) will drop the high side and improve cooling. Check the condenser face for debris and verify the radiator/condenser fan is engaging on AC demand.

Service problemR-744 (CO2, transcritical)

Reading an R-744 transcritical supermarket system

Scenario · Supermarket R-744 transcritical commercial refrigeration system at 95°F outdoor — above CO2 critical temperature (87.8°F). Medium-temp and low-temp evaporator circuits feed a single high-pressure gas cooler.

Measured

MT suction

290 PSIG

LT suction

40 PSIG

Gas cooler

1350 PSIG

Ambient

95°F

PT chart lookup (R-744)

290 PSIG0°F satMT evaporator — sub-critical

40 PSIG−50°F satLT evaporator — sub-critical

1350 PSIGout of rangeno saturation above 87.8°F critical point

Result · High side is transcritical — different rules apply

The 1350 PSIG gas cooler discharge is controlled by a high-pressure throttle valve, not by ambient-driven condensation. No saturation state exists above the critical temperature, so "subcooling" as a concept does not apply on the high side — the PT calculator correctly returns "out of range".

Fix

For transcritical high-side health, measure gas cooler outlet temperature directly — target is 8-10°F above ambient at design optimum (so 103-105°F at 95°F outdoor). The high-pressure valve setpoint controls system COP and should be tuned per OEM service literature, not by PT chart lookup.

Service problemR-410A (heat pump)

Reading an R-410A heat pump in heating mode at 30°F outdoor

Scenario · R-410A residential air-source heat pump in heating mode. 30°F outdoor (outdoor coil is now the evaporator), 70°F indoor return air (indoor coil is now the condenser). Customer reports the unit runs but the home doesn't feel warm.

Measured

Suction P

70 PSIG

Discharge P

320 PSIG

Outdoor temp

30°F

Indoor return

70°F

PT chart lookup (R-410A — reversed cycle)

70 PSIG14°F satoutdoor coil — now the evaporator

320 PSIG99°F satindoor coil — now the condenser

Interpretation

Outdoor coil = 30°F − 14°F = 16°F below ambientnormal heating-mode evaporator

Indoor coil = 99°F − 70°F = 29°F above returnthe temperature lift

OK · Normal heat-pump heating-mode operation

Outdoor coil saturation must run below ambient to absorb heat — 14°F below freezing means frost on the outdoor coil is expected, managed by defrost cycles. Indoor coil 29°F above return air delivers a supply temperature around 95-100°F, cooler than gas-furnace heat but normal for heat pumps.

Fix

If the unit feels "not warming" despite normal readings, check defrost cycle operation (frost accumulation blocks airflow) and verify auxiliary heat is engaging when needed. Abnormally high outdoor saturation (say, 25°F at 30°F ambient) would suggest compressor or charge issues — these readings are healthy.

Operating pressure ranges by refrigerant — quick reference table

Typical operating pressure ranges across major refrigerants and applications. These are field-service reference ranges, not exact values — actual operating pressures depend on charge, ambient, load, superheat, subcooling, and equipment-specific conditions.

Refrigerant	Application	Suction PSIG	Discharge PSIG
R-410A	Residential AC, 95°F ambient	120-140	350-400
R-32	Residential AC, 95°F ambient	130-145	360-410
R-454B	Residential AC, 95°F ambient	115-135	340-385
R-22	Residential AC (legacy), 95°F	65-80	240-290
R-407C	R-22 retrofit AC, 95°F	70-90	280-330
R-404A	Low-temp commercial, neg twenty evap	15-25	250-290
R-448A	Low-temp commercial retrofit	13-20	230-270
R-454C	Low-temp commercial new	5-12	220-260
R-134a	Centrifugal chiller, 45°F evap	35-45	145-180
R-513A	Chiller retrofit, 45°F evap	38-48	155-190
R-1234yf	Mobile AC, 100°F ambient	30-45	220-260
R-744 (sub-critical)	Cold-ambient CO2 refrigeration	200-500	600-900
R-744 (transcritical)	Warm-ambient CO2 refrigeration	290-470	1100-1700
R-290	Heat pump, 95°F ambient	70-90	200-260
R-717	Industrial low-temp, neg twenty evap	4-8	165-200

Source: ASHRAE Handbook of Refrigeration 2022, ACCA Manual T, equipment OEM service literature. Actual operating ranges vary by equipment design and operating conditions.

Saturation pressure quick reference — common service temperatures

Saturation pressure values at common service temperatures across mainstream refrigerants. All values are PSIG from CoolProp 7.2.0. For zeotropic blends, bubble / dew values shown.

Refrigerant	32°F	45°F	70°F	95°F	120°F
R-22	58	76	121	181	260
R-410A	102	130	202	278	380
R-32	110	142	206	296	410
R-454B	99	128	190/184	262/256	360/350
R-134a	28	40	71	124	187
R-404A	73	97	148	232	332
R-407C	53/43	75/63	141/117	215/180	305/258
R-454C	30/22	47/35	141/112	220/185	305/255
R-744 (CO2)	491	595	838	transcritical	transcritical
R-290	56	74	110	175	250
R-717 (NH3)	47	62	114	181	270

Use this table for quick mental reference. For exact values at any temperature, use the calculator above. Source: CoolProp 7.2.0; values verified against AHRI Standard 700-2019 specifications.

Saturation pressure at 95°F across mainstream refrigerants, descending — visual companion to the quick-reference table. Zeotropic blends shown at bubble pressure. R-744 (CO2) is transcritical at 95°F and omitted (no saturation state above 87.8°F).

Common PT lookup mistakes — and how to avoid them

PT calculator results can mislead service decisions when applied incorrectly. The five most common mistakes:

PSIG vs PSIA confusion. Service manifold gauges read PSIG; the PT calculator uses PSIG by default. Confusing the two introduces a 14.696 PSI offset (PSIA = PSIG + 14.696 at sea level, slightly less at altitude).
Wrong curve on zeotropic blends. Using bubble pressure for superheat measurement on R-407C, R-454C, R-455A introduces error equal to the glide (11-22°F). Always use the dew curve for superheat (suction line), the bubble curve for subcooling (liquid line). Pure refrigerants and azeotropes have a single curve, so this concern does not apply.
Saturation pressure is not operating pressure. The PT calculator gives saturation pressure at thermodynamic equilibrium. Actual operating pressure on a running system depends on charge, ambient, load, superheat, subcooling, and line pressure drop. Saturation is the reference; operating values vary around it.
Extrapolating beyond chart range.The calculator returns "out of range" outside the chart's valid temperature range — this is correct physics, not a bug. R-744 has no saturation state above 87.8°F (its critical point); other refrigerants have similar validity limits at extremes.
Ignoring line pressure drop. The pressure at the manifold service port differs slightly from the pressure at the compressor or evaporator due to line pressure drop. For most residential applications the drop is small and ignorable; for long line sets, large commercial systems, or systems with substantial filter-drier pressure drop, the effect is more meaningful. Account for line losses when interpreting manifold readings against design conditions.

Pressure unit conversions reference

The PT calculator supports °F / PSIG and °C / kPa unit pairs. Other pressure unit conversions are sometimes needed in HVAC service:

From	To	Multiplier
PSIG	PSIA	plus 14.696 (at sea level)
PSIG	kPa (gauge)	times 6.8948
PSIG	bar (gauge)	times 0.06895
PSIG	inHg vacuum (below atmospheric)	times negative 2.036
kPa (gauge)	kPa (absolute)	plus 101.325
bar	PSIG	times 14.504
MPa	PSIG	times 145.04
Pa	kPa	divided by 1000

For temperature conversions: °F = (°C times nine over five) plus 32; °C = (°F minus 32) times five over nine. The calculator handles both temperature units automatically; this conversion table is for reference when reading equipment data plates in unfamiliar units.

When to use this calculator vs the others

The PT calculator is the foundational lookup tool. Other calculators on the site build on PT lookups for specific service tasks:

PT Calculator (this page) — pressure-temperature lookup, either direction, for any refrigerant. Use for quick reference, retrofit comparison, or as a building block in manual calculations.
Superheat Calculator — adds suction-line temperature input, computes superheat with automatic dew/bubble curve selection. Use for charging fixed-orifice systems or for diagnostic superheat measurement on any system.
Subcooling Calculator — adds liquid-line temperature input, computes subcooling with automatic curve selection. Use for charging TXV systems or for diagnostic subcooling measurement.
Combined SH/SC/PT Calculator — both suction and liquid line inputs, computes superheat and subcooling together, displays diagnostic pattern banner (undercharge/overcharge/restriction/airflow).
PT Comparison Tool — overlays 2-4 refrigerants' PT curves on a single chart. Use for retrofit pressure-envelope comparison.
Retrofit Compatibility Calculator — pair comparison covering lubricant compatibility, safety class, pressure envelope, and glide. Use for retrofit decision-making beyond just pressure comparison.

Sources behind the calculator data

All saturation values come from primary references with documented provenance:

CoolProp 7.2.0(Bell, Wronski, Quoilin, Lemort 2014, doi:10.1021/ie4033999) — REFPROP-compatible Helmholtz EOS implementation. Source for pure refrigerants (R-22, R-32, R-134a, R-744, etc.) and CoolProp's predefined mixtures (R-410A, R-407C, R-404A, etc.). Accuracy typically better than ±0.5 percent across the operating range.
AHRI Standard 700-2019 — Specifications for Refrigerants. Used to verify CoolProp values against the manufacturer-specification standard.
Manufacturer technical datasheets — for the 11 blends not modeled by CoolProp (R-448A, R-450A, R-1336mzz(Z), R-454C blended mode, etc.). Honeywell, Chemours, Arkema, and AGC PT charts cited on each refrigerant detail page.
ASHRAE Standard 34-2022 — Designation and Safety Classification of Refrigerants. Source for composition specifications and safety class assignments.
ASHRAE Handbook of Refrigeration 2022 — Application context, operating range references, service procedure guidance.
ACCA Manual T — Air-Side and Refrigerant-Side Diagnostics. Field service interpretation context for PT lookup applications.

Each refrigerant's detail page (linked from the dropdown) cites the specific data source for that refrigerant's PT chart.

How to use this calculator

Pick a refrigerant from the dropdown. Defaults to R-410A.
Choose direction: 'Pressure from temperature' (PT chart lookup) or 'Temperature from pressure' (inverse).
Adjust unit toggles if you need metric values (°C / kPa).
Enter your value. The result updates immediately, with both bubble and dew for zeotropic blends.
Cross-reference against the equipment data plate and the worked examples below to interpret the result for your specific scenario.

Common errors

Confusing PSIG (gauge) with PSIA (absolute). Manifold gauges read PSIG; PSIA = PSIG + 14.696.
Using the bubble pressure for superheat math on a zeotropic blend — use the dew pressure instead. The superheat calculator handles this automatically when a zeotropic blend is selected.
Treating saturation pressure as operating pressure. Saturation is the thermodynamic reference; operating pressure depends on charge, ambient, load, superheat, and subcooling.
Extrapolating beyond the chart range. R-744 has no saturation state above 87.8°F (the critical temperature); the calculator returns 'out of range' rather than producing a fabricated value.

Underlying math

Formula

P_sat = f(T) or T_sat = f(P) Linear interpolation between adjacent 1°F data points in the refrigerant's PT chart. For zeotropic blends, both bubble (saturated liquid) and dew (saturated vapor) curves are interpolated independently.

Source

Saturation pressures from CoolProp 7.2.0 (Bell, Wronski, Quoilin, Lemort 2014, doi:10.1021/ie4033999), REFPROP-compatible Helmholtz EOS. For the 11 manufacturer-blend refrigerants not in CoolProp's reference library (R-448A, R-450A, R-1336mzz(Z), R-454C blended-data-mode, etc.), values come from the named manufacturer PT charts cited on each refrigerant's detail page. Cross-checked against AHRI Standard 700-2019 refrigerant specifications.

Worked example

R-410A at 70°F: CoolProp returns P_bubble = 201.76 PSIG, P_dew = 201.07 PSIG (0.7 PSI glide — near-azeotropic). R-407C at 70°F: CoolProp returns P_bubble = 140.52 PSIG, P_dew = 117.29 PSIG (23 PSI glide — significant zeotrope). R-744 (CO2) at 70°F: P_sat = 838.13 PSIG. Above 87.8°F (the critical point) no saturation state exists and the chart truncates. R-32 at 95°F: 296 PSIG saturation. R-410A at 95°F: 278 PSIG. The 5-8 percent R-32 pressure premium over R-410A is consistent across the operating envelope.

Related tools

Superheat Calculator

Suction-line PSIG plus measured °F to superheat, with diagnostic context.

Subcooling Calculator

Liquid-line PSIG plus measured °F to subcooling.

Combined SH/SC/PT

Both sides plus pattern-matching diagnostic banner in one workflow.

PT Comparison Tool

Overlay 2-4 refrigerants' PT curves for side-by-side comparison.

Retrofit Compatibility

Pair comparison: lubricant, safety class, pressure envelope, glide.

Frequently asked

›What's the difference between PSI, PSIG, and PSIA?

PSI is a generic pressure unit (pounds per square inch). PSIG is gauge pressure — pressure above atmospheric (0 PSIG = 14.696 PSIA at sea level). PSIA is absolute pressure measured from a perfect vacuum. Service manifold gauges read in PSIG. All values on this calculator and across hvacptcharts.com are PSIG unless explicitly stated as PSIA. Convert with PSIA = PSIG + 14.696.

›Why do some refrigerants show two pressures (bubble and dew)?

Zeotropic blends boil and condense across a temperature range at constant pressure rather than at a single temperature. The bubble pressure is the saturation pressure of the liquid (where vapor first forms); the dew pressure is the saturation pressure of the vapor (where the last liquid disappears). The temperature difference at the same pressure is the glide. For pure refrigerants (R-22, R-134a, R-32) and azeotropes (R-507A, R-500) the two values coincide.

›How accurate is the calculator?

Saturation pressures come from CoolProp 7.2.0 (REFPROP-compatible Helmholtz EOS). For pure refrigerants and predefined CoolProp mixtures, accuracy is typically better than ±0.5% across the operating range. For the 11 manufacturer-blend refrigerants not modeled by CoolProp (R-448A, R-450A, R-1336mzz(Z), etc.) values come directly from the named manufacturer's PT chart with the same accuracy as the source datasheet.

›What temperature range does the calculator cover?

Default coverage is -40°F to 150°F at 1°F increments — 191 data points per refrigerant. Sub-critical refrigerants are truncated at their critical temperature where no saturation state exists. R-744 (CO2) stops at 87°F (critical temperature 87.8°F); R-13 at 84°F; R-1150 (ethylene) at 48°F. Outside the chart range the calculator returns 'out of range' rather than extrapolating values that don't correspond to physical saturation.

›Can I get PT values in metric units?

Yes — toggle the unit set to °C / kPa. The kPa values are gauge (kPa above atmospheric, where atmospheric is 101.325 kPa). For absolute kPa, add 101.325. The calculator handles both unit systems with the same underlying CoolProp data.

›How does this PT calculator differ from the superheat and subcooling calculators?

The PT calculator does pressure-to-temperature lookup in either direction — it answers 'what's the saturation pressure at this temperature?' or 'what's the saturation temperature at this pressure?' The superheat and subcooling calculators add the line-temperature input and compute the temperature difference: superheat = suction line temperature − saturation temperature at suction pressure (using the dew curve for blends); subcooling = saturation temperature at discharge pressure (bubble curve for blends) − liquid line temperature.

›Why do operating pressures differ from saturation pressures?

Saturation pressure is the thermodynamic equilibrium pressure at a given temperature. Operating pressure on a running system depends on refrigerant charge, ambient temperature, indoor load, superheat, subcooling, and line pressure drop. The PT chart gives the reference value; actual gauge readings on a running system vary around the saturation reference based on these operating factors.

›Can I use the calculator for retrofit decisions?

Yes — the PT calculator is useful for understanding the pressure envelope of candidate retrofit refrigerants relative to the original equipment design. Compare R-22 saturation values to R-407C bubble/dew values to see the retrofit pressure delta. Compare R-410A to R-32 saturation to confirm the small 5-8% pressure increase that R-32 introduces. For pair comparisons with full retrofit guidance, use the refrigerant comparison and retrofit compatibility tools.