Subcooling Calculator

Enter your liquid-line pressure and temperature for any refrigerant; get subcooling plus diagnostic context. Bubble-curve math so high-glide blends (R-407C, R-454C, R-455A) don't read 11-22°F off.

What subcooling is and why it matters

Subcooling is the temperature of liquid refrigerant below its saturation temperature at the same pressure. At any discharge pressure, the saturation temperature is the boundary above which any refrigerant is vapor; once the refrigerant has fully condensed and continues to lose heat to the condenser airstream, every degree below that saturation reading is one degree of subcooling.

On a working system, subcooling serves two purposes. First, it guarantees liquid (not flash gas) is reaching the metering device — a TXV or fixed-orifice device fed with two-phase refrigerant loses massive capacity because the orifice meters by volume, and vapor takes up most of the volume with little cooling effect. Second, subcooling indirectly measures refrigerant charge: more refrigerant in the system means more liquid backed up in the condenser, which means more subcooling.

Schematic of a residential split-system liquid line, showing the smaller uninsulated copper line, the probe location at the outdoor service valve, and the high-side manifold pressure port. Source: Carrier / Trane / Lennox residential service literature.

Subcooling is the TXV charging signal

For TXV / EEV residential AC and most commercial systems, subcooling is the primary charging metric — superheat is determined by the valve, but subcooling is determined by how much refrigerant you have. Match the SC target, and the system is charged.

When to use SC vs SH for charging — the metering-device rule

The reason TXV systems are charged by subcooling and fixed-orifice systems by superheat traces to what each device controls. A TXV regulates superheat to its setpoint by modulating refrigerant flow; charge changes do not directly alter superheat on a TXV system (the valve compensates). But charge changes do alter subcooling: more refrigerant means more liquid in the condenser, raising SC.

Fixed-orifice devices (pistons, capillary tubes, accurators) have no feedback control. Superheat varies directly with charge, ambient temperature, and indoor load. Subcooling on a fixed-orifice system is informational — it depends on too many factors to give a clean charge reading.

Metering device → charging metric

Device	Charge by	Verify with	Target SC
TXV	Subcooling	SH at TXV setpoint (8-15°F)	8-12°F
EEV	Subcooling	EEV diagnostic + SH	5-12°F
Fixed orifice (piston, captube)	Superheat (ACCA chart)	SC informational	Varies 0-15°F

On a TXV residential split system, the standard procedure is: charge to 10°F SC, then verify SH is somewhere in 8-15°F as a sanity check. If SC lands on target but SH is way off (very low or very high), the issue is not charge — it's the valve, the airflow, or the load.

Target subcooling reference — by application and equipment type

Target subcooling by application

Application	Target SC	Source
Residential AC, TXV (R-410A, R-32, R-454B)	8-12°F	Carrier, Trane, Lennox, Daikin OEM
Heat pump, cooling mode	8-15°F	Carrier / Trane heat-pump service guides
Heat pump, heating mode (indoor coil = condenser)	8-15°F	Carrier / Trane heat-pump service guides
Walk-in cooler (medium-temp)	5-15°F	ASHRAE Handbook of Refrigeration 2022 Ch. 23
Walk-in freezer (low-temp)	5-15°F	ASHRAE Handbook of Refrigeration 2022 Ch. 23
Mini-split with long line set (>50 ft)	12-15°F	Mitsubishi, Daikin, LG line-set adjustment tables
Centrifugal chiller at condenser exit	2-5°F	ASHRAE HVAC Systems & Equipment 2024 Ch. 43
Refrigerated transport (high SC for distance)	15-25°F	Carrier Transicold service literature
Mobile AC (R-1234yf, R-134a)	5-10°F	SAE J2912 (MAC service procedures)

Target subcooling ranges across HVAC applications. Long-line-set residential mini-splits run higher SC at the outdoor unit to compensate for line-set heat pickup and pressure drop. Refrigerated transport runs the highest SC of common applications because of long line distances and high heat exposure.

Real service problems solved with subcooling measurement

Ten field scenarios covering residential AC TXV charging (the primary use case), undercharge / overcharge / fouling pattern recognition, zeotropic blend bubble-curve handling, heat pump dual-mode operation, chiller condenser approach diagnostics, and long-line-set installation. Each shows what gets measured, the chart lookup, the derivation, and the verdict.

Service problemR-410A (TXV)

Charging an R-410A TXV residential AC by subcooling

Scenario · New R-410A TXV residential AC, 95°F outdoor day, system has been running 20 minutes. You are setting the charge by subcooling per the nameplate (10°F target SC stamped on the outdoor unit data plate).

Measured

Discharge P

380 PSIG

Liquid line

100°F

Suction P

130 PSIG

Suction line

60°F

PT chart lookup (R-410A)

380 PSIG111°F satcondenser saturation

130 PSIG45°F satevap saturation (for SH cross-check)

Derived

Subcooling = 111°F − 100°F = 11°Fmatches 10°F target ±1°F

Superheat = 60°F − 45°F = 15°FTXV in 8-15°F range

OK · Properly charged — TXV operating

Subcooling matches the 10°F nameplate target within tolerance; superheat cross-check confirms TXV is regulating. No further service action.

Service problemR-410A (TXV)

Negative subcooling — flash gas in the liquid line

Scenario · Same R-410A TXV system, three months after install. Customer reports the unit runs constantly but doesn't cool. You hook up gauges and read concerning numbers.

Measured

Discharge P

320 PSIG

Liquid line

108°F

Suction P

100 PSIG

Suction line

75°F

PT chart lookup (R-410A)

320 PSIG99°F satcondenser saturation

100 PSIG31°F satevap saturation

Derived

Subcooling = 99°F − 108°F = −9°Fnegative — liquid line warmer than saturation

Superheat = 75°F − 31°F = 44°Fvery high — confirms undercharge

Action required · Undercharge — significant leak

Negative subcooling means there is no liquid column in the condenser — flash gas (two-phase) is reaching the metering device. High superheat confirms the evaporator is starved. The system is significantly undercharged; a leak is the most likely cause given the recent commissioning.

Fix

Find and repair the leak per EPA Section 608 before adding refrigerant. Standard leak-search procedure: electronic leak detector along all joints and accessible line segments, soap solution for confirmation, UV dye if the leak is intermittent or hidden. After repair: evacuate to 500 microns, hold ≥30 min, charge by weight to nameplate.

Service problemR-410A (TXV)

Very high subcooling — overcharge or condenser fouling?

Scenario · R-410A TXV system, two years old. Customer reports the unit runs longer than it used to and the electric bill is higher. You measure subcooling at 22°F — well above the 10°F target. Two suspects: overcharge or dirty condenser. Which?

Measured

Discharge P

440 PSIG

Liquid line

98°F

Ambient

95°F

Air off cond

115°F

PT chart lookup (R-410A)

440 PSIG120°F satcondenser saturation (very high)

Derived

Subcooling = 120°F − 98°F = 22°Fvery high

Condenser approach = 120°F − 115°F = 5°Fapproach is normal — fouling NOT the cause

Cond above ambient = 120°F − 95°F = 25°Fvery high — should be ~15-20°F

Action required · Overcharge — condenser is healthy

High SC with normal condenser approach (5°F) and high condenser-above-ambient delta confirms overcharge: excess refrigerant fills the condenser, raising saturation temperature for the same heat rejection load. If approach were also high (12-18°F), fouling would be the cause. The 5°F approach proves the coil is clean and airflow is good.

Fix

Recover refrigerant in 1-2 oz increments using a recovery / charging scale. After each increment, allow 10-15 minutes for steady state, then re-test SC. Stop when SC reaches 10°F. Also verify SH lands in 8-15°F as a final cross-check.

Service problemR-410A (TXV)

High SC with high condenser approach — this IS condenser fouling

Scenario · Same R-410A TXV system, customer reports the AC isn't cooling well during peak heat. You measure 18°F SC (high) but the air off the condenser is noticeably hotter than usual. Are we sure it's not overcharge?

Measured

Discharge P

420 PSIG

Liquid line

99°F

Ambient

95°F

Air off cond

105°F

PT chart lookup (R-410A)

420 PSIG117°F satcondenser saturation (very high)

Derived

Subcooling = 117°F − 99°F = 18°Fhigh

Condenser approach = 117°F − 105°F = 12°Fhigh — should be 3-7°F clean coil

Cond above ambient = 117°F − 95°F = 22°Fvery high

Action required · Condenser fouling — clean before adjusting charge

High SC AND high approach is the fouling fingerprint, not overcharge. The condenser is holding extra liquid (high SC) because heat-transfer fouling raises saturation temperature; the high approach proves the coil isn't rejecting heat efficiently. Fixing this with refrigerant recovery would mask the real problem and leave the system undercharged once the coil is clean.

Fix

Clean the condenser coil (compressed air or condenser cleaner per OEM service procedure), then re-test SC at steady state. If SC drops to 8-12°F after cleaning, the charge was correct. If SC remains high after cleaning, then recover refrigerant in increments until SC reaches 10°F target.

Service problemR-407C (zeotropic ~11°F glide)

R-407C subcooling — why curve selection matters

Scenario · R-407C retrofit on a residential AC originally R-22. R-407C is zeotropic with ~11°F glide, so the bubble vs dew distinction matters significantly for subcooling calculation.

Measured

Discharge P

320 PSIG

Liquid line

98°F

PT chart lookup (R-407C — dual curves)

320 PSIG bubble118°F satUSE THIS — cond outlet saturation

320 PSIG dew107°F satcond inlet — wrong for SC

Derived (correct vs wrong-curve)

Subcooling (bubble, correct) = 118°F − 98°F = 20°Fhigh — overcharge?

Subcooling (dew, wrong) = 107°F − 98°F = 9°Fwould falsely look normal

Investigate · Investigate overcharge or fouling — dew curve would have hidden it

The correct bubble-curve calculation shows SC = 20°F, well above the 8-12°F target — flags overcharge or condenser fouling for investigation. Using the wrong dew curve would have shown SC = 9°F and signed off the system as properly charged. Wrong-curve error = 11°F = R-407C glide.

Fix

For zeotropic blends (R-407C, R-454C, R-455A, R-448A, R-449A), always confirm PT chart software is using the bubble curve at discharge pressure for subcooling. This calculator does it automatically. Check condenser airflow and coil cleanliness; if those are fine, recover refrigerant in increments.

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

R-454C low-temp walk-in freezer subcooling check

Scenario · R-454C walk-in freezer, low-temp commercial, -20°F target evaporator. R-454C replaces R-404A as a sub-700 GWP option under the AIM Act. Wide 14°F glide means curve selection matters even more.

Measured

Discharge P

200 PSIG

Liquid line

82°F

Ambient

95°F

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

200 PSIG bubble88°F satUSE THIS — cond outlet saturation

200 PSIG dew74°F satcond inlet — wrong for SC

Derived

Subcooling (bubble, correct) = 88°F − 82°F = 6°Fin 5-15°F LT walk-in target

Wrong-curve error = 14°F = R-454C glidedew would give SC = −8°F

OK · Within target — bubble curve gives correct answer

6°F subcooling using the correct bubble curve is at the low end of the 5-15°F walk-in freezer range. Wide line runs (typical for walk-in installations) often shift SC toward the higher end of the range; if this freezer has short lines, the low end is appropriate.

Service problemR-134a (centrifugal chiller)

R-134a centrifugal chiller — why SC is low by design

Scenario · Water-cooled R-134a centrifugal chiller, 45°F leaving chilled water, 85°F entering condenser water. You measure subcooling at 3°F and worry it's undercharged. Should you add refrigerant?

Measured

Discharge P

152 PSIG

Liquid line

110°F

Leaving CHW

45°F

Leaving CW

95°F

PT chart lookup (R-134a)

152 PSIG113°F satcondenser saturation

Derived

Subcooling = 113°F − 110°F = 3°Fchiller target 2-5°F

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

OK · Subcooling normal — but condenser fouling needs attention

3°F SC is within the chiller 2-5°F design range — chillers run lower SC than residential AC because the flooded-evaporator design and high-side liquid sump handle hold-up rather than relying on condenser sub-cooling. The high condenser approach (18°F vs target 5-10°F) is the real issue: condenser tubes need cleaning or condenser water flow is restricted.

Fix

Do NOT add refrigerant. Schedule a condenser tube brush-and-flush per chiller OEM procedure. Verify condenser water flow rate against nameplate; check for stuck bypass valves or strainer blockage. Re-test SC after cleaning — should remain within 2-5°F target.

Service problemR-410A (heat pump cooling mode)

Heat pump cooling mode subcooling — same as straight AC?

Scenario · R-410A residential air-source heat pump running in cooling mode. You want to confirm SC behaves the same as a straight AC condenser; the heat pump has a reversing valve and dual TXVs which complicates the picture.

Measured

Discharge P

395 PSIG

Liquid line

102°F

Ambient

95°F

Indoor return

75°F

PT chart lookup (R-410A)

395 PSIG114°F satoutdoor coil (= condenser in cooling)

Derived

Subcooling = 114°F − 102°F = 12°Fheat pump cooling target 8-15°F

OK · Properly charged for cooling mode

12°F SC is in the heat pump cooling-mode target range. Heat pump systems typically have a slightly wider SC target than straight AC (8-15°F vs 8-12°F) because of the dual-mode TXV / accumulator design — extra SC margin ensures liquid column in both cooling and heating mode operation. Verify nameplate for the specific installation.

Fix

For full heat pump commissioning, test SC in BOTH cooling mode (outdoor coil = condenser) and heating mode (indoor coil = condenser). Heat pump charge is often checked in heating mode after a service call, since heating mode is where most performance complaints arise. Verify defrost cycle operation and reversing valve actuation at the same visit.

Service problemR-32 (mini-split, long line set)

Mini-split with 75-ft line set — adjusting target SC

Scenario · Daikin / Mitsubishi-style R-32 mini-split with a 75-ft pre-charged line set running through unconditioned attic. OEM nameplate target SC is 10°F at the outdoor unit, but the long line set requires adjustment per the OEM service literature.

Measured

Discharge P

395 PSIG

Liquid line at OU

100°F

Line length

75 ft

Lift

10 ft

PT chart lookup (R-32)

395 PSIG111°F satoutdoor coil saturation (R-32 pure)

Derived

Subcooling at OU = 111°F − 100°F = 11°Fbelow long-line target

Long-line target (75 ft) = 13°F per OEM table+2-3°F per 25 ft over 25-ft baseline

Investigate · Under target for long-line installation — add small charge

For line sets over 25 feet, OEMs (Mitsubishi, Daikin, Fujitsu) specify higher subcooling at the outdoor unit to ensure sufficient liquid column reaches the indoor TXV. The 75-ft line set adds ~3°F to the baseline 10°F target; your reading of 11°F is below the 13°F long-line target.

Fix

Add refrigerant in 2-4 oz increments per the OEM line-length charge correction table (typically +0.4 to 0.6 oz per foot over 25 ft for R-32 / R-410A mini-splits). Re-test SC at the outdoor unit until it reaches the long-line target. Verify superheat at the indoor unit lands in 8-15°F.

Service problemR-744 (CO2, transcritical)

R-744 transcritical — there is no subcooling on the high side

Scenario · Supermarket R-744 transcritical commercial refrigeration system at 95°F outdoor (above CO2 critical 87.8°F). New technician asks: what's the subcooling target on the gas cooler exit?

Measured

Gas cooler outlet P

1350 PSIG

Gas cooler outlet T

105°F

Ambient

95°F

PT chart lookup (R-744)

1350 PSIGout of rangeno saturation above 87.8°F critical point

Result · Subcooling does not apply in transcritical mode

Above the CO2 critical temperature (87.8°F), no saturation state exists — there's no liquid / vapor distinction, so the concept of subcooling doesn't apply. Instead, the meaningful high-side metric is gas cooler outlet temperature approach: typically 8-10°F above ambient at design (so 103-105°F at 95°F outdoor). Your 105°F reading is right at the design point.

Fix

For transcritical systems, optimize high-pressure throttle valve setpoint per OEM to maintain target gas cooler outlet temperature. Below the critical temperature (cold-ambient sub-critical mode), R-744 condenses normally and standard SC math applies. Many supermarket R-744 systems switch between modes seasonally.

Six common subcooling measurement mistakes

Wrong curve on zeotropes. Using dew pressure for saturation temperature on R-407C / R-454C / R-455A / R-448A / R-449A overestimates subcooling by the glide value (11-22°F). This calculator uses the bubble curve automatically — verify any paper PT chart shows both columns and use the bubble column for SC.
Probing the wrong line. The liquid line is the smaller, uninsulated copper line at the outdoor unit service valve. The suction line is larger and foam-insulated. Probing the suction line gives you a superheat measurement, not subcooling.
High SC interpreted as "extra capacity". High SC actually reduces capacity — excess refrigerant in the condenser raises condensing pressure (more compressor work) and reduces effective condenser area for vapor condensation. Always investigate high SC, never celebrate it.
Confusing fouling for overcharge. Both produce high SC, but condenser approach distinguishes them: high SC + high approach = fouling (clean the coil), high SC + normal approach = overcharge (recover refrigerant). Always check approach before adjusting charge.
Ignoring line-set length on mini-splits.Long line sets (>50 ft) require higher SC at the outdoor unit to deliver adequate SC at the indoor TXV. Mitsubishi, Daikin, LG, and Fujitsu all publish line-length correction tables — use them.
Reading before steady state.Subcooling stabilizes 10-20 minutes after compressor start. Brief transient values after defrost or cycle changes aren't charge-decision data — wait for steady state.

When to use this calculator vs the others

Subcooling Calculator (this page) — liquid-line measurement. Primary charging signal for TXV / EEV systems. Diagnose condenser-side issues (fouling, overcharge, low ambient airflow, non-condensables).
Superheat Calculator — suction-line measurement. Charge fixed-orifice systems; verify TXV operation; diagnose evaporator-side issues (undercharge, restriction, flooding). Always pair with SC.
Combined SH / SC / PT — both sides plus pattern-matching diagnostic banner. Use for full system commissioning or comprehensive diagnostic.
PT Calculator — raw saturation lookup, no measurement input. Reference tool for cross-checking or comparing refrigerants.
System Pressure Diagnostic — high-low pressure × high-low SH / SC pattern matcher. Use when you have all four values and want a quick fingerprint identification.
High head pressure causes — companion guide when SC and head pressure are both high. Decision tree for condenser-side troubleshooting.

Primary sources behind the calculator and content

CoolProp 7.2.0 (Bell, Wronski, Quoilin, Lemort 2014, doi:10.1021/ie4033999) — REFPROP-compatible Helmholtz EOS for all saturation temperatures. Accuracy typically better than ±0.5% across operating range.
ACCA Manual T "Air-Side and Refrigerant-Side Diagnostics" (2017) — TXV charging procedure (subcooling-based), condenser fouling vs overcharge distinction, common error patterns. Industry-standard reference.
ASHRAE Handbook of Refrigeration 2022 — Chapter 23 (service procedures), target subcooling by application for commercial refrigeration.
ASHRAE HVAC Systems & Equipment 2024 — Chapter 43 (chillers), centrifugal chiller subcooling targets and condenser approach.
EPA Section 608 (40 CFR Part 82 Subpart F) — refrigerant handling certification, leak repair requirements before adding refrigerant.
SAE J2912 / J639 — mobile AC service procedures (R-1234yf, R-134a SC targets).
OEM service literature — Carrier, Trane, Lennox, Daikin, Mitsubishi, Goodman, LG, Fujitsu charging procedures, target SC ranges per model, and line-set length correction tables.

How to use this calculator

Pick the refrigerant. Defaults to R-410A.
Read the high-side (discharge / liquid-line) pressure from the manifold gauge.
Clamp a contact temperature probe on the liquid line at the outdoor unit's service valve — the smaller, uninsulated copper line. Insulate from ambient.
Allow 10-20 minutes after compressor start for steady-state. Enter both values.
Compare against your equipment's target subcooling (TXV target typically 8-12°F; check the OEM nameplate or service manual for the specific equipment).

Common errors

Probing the wrong line. The LIQUID line is the smaller, uninsulated line at the outdoor unit; the suction line is larger and foam-insulated.
Confusing high subcooling for 'extra capacity' — it usually means overcharge or condenser fouling, both of which reduce capacity.
On zeotropic blends, using the dew curve at the discharge pressure — overestimates subcooling by the glide value (11°F for R-407C). This calculator uses the bubble curve automatically.
Forgetting line set length adjustments — long mini-split line sets require higher SC at the outdoor unit to deliver adequate SC at the indoor TXV.

Underlying math

Formula

Subcooling (°F) = T_sat(P_liquid) − T_liquid_line T_sat is read off the BUBBLE curve at the measured liquid pressure for zeotropic blends. For pure refrigerants and azeotropes, bubble ≡ dew, so the curve choice is moot.

Source

Saturation temperatures from CoolProp 7.2.0 (Bell, Wronski, Quoilin, Lemort 2014, doi:10.1021/ie4033999), REFPROP-compatible Helmholtz EOS. Target subcooling per equipment manufacturer service literature (Carrier, Trane, Lennox, Daikin, Goodman), ACCA Manual T (2017), ASHRAE Handbook of Refrigeration 2022 (Chapter 23), and ASHRAE HVAC Systems & Equipment 2024 (Chapter 43, chillers).

Worked example

R-410A residential AC TXV system, 95°F outdoor: Liquid pressure: 380 PSIG Liquid-line temperature: 100°F Saturation temperature at 380 PSIG: 111°F (CoolProp 7.2.0) Subcooling = 111 − 100 = 11°F Within the typical 8-12°F TXV target range. TXV systems are charged BY subcooling — adjust refrigerant in 1-2 oz increments until SC lands on target (usually 10°F).

Related tools

Superheat Calculator

Suction-line companion. Together they pin down a system's charge state.

Combined PT / SH / SC

All three measurements on one form with pattern-matching diagnostic banner.

PT Calculator

Raw saturation lookup for any refrigerant.

High head pressure causes

High SC often signals a condenser-side condition. Diagnostic decision tree.

System Diagnostic

Pattern matcher for high/low pressure × high/low SH/SC fingerprints.

Frequently asked

›What is subcooling?

Subcooling is the temperature of liquid refrigerant below its saturation temperature at the same pressure. It is measured on the liquid line leaving the condenser: condenser saturation temperature minus measured liquid-line temperature equals subcooling. Positive subcooling confirms fully-liquid refrigerant entering the metering device; zero or negative subcooling means vapor bubbles (flash gas) are present, starving the metering device and reducing capacity.

›What is the target subcooling for an HVAC system?

TXV / EEV residential AC: 8-12°F at the condenser outlet (per Carrier, Trane, Lennox, Daikin OEM service literature). Heat pumps in cooling mode: 8-15°F; in heating mode the indoor coil becomes the condenser and target is similar. Walk-in commercial refrigeration: 5-15°F depending on line run length. Centrifugal chillers: 2-5°F at the condenser exit. Fixed-orifice residential systems are charged by superheat — subcooling is informational only. Always cross-check the equipment label and OEM service literature.

›How do I measure subcooling in the field?

Read the high-side (discharge / liquid-line) pressure from the manifold gauge in PSIG. Clamp a contact temperature probe on the liquid line at the outdoor unit's service valve — the smaller, uninsulated copper line. Make solid metal-to-metal contact, insulate from ambient air, and let the reading stabilize (10-20 minutes after compressor start). Convert the liquid pressure to saturation temperature using a PT chart for your refrigerant — use the bubble curve for zeotropic blends. Subtract: subcooling = T_sat − T_line. This calculator handles the conversion and bubble-curve selection automatically.

›What does low subcooling indicate?

Low subcooling (under 3°F on a TXV system) usually means undercharge — the compressor can't condense enough vapor to fill the condenser with a liquid column, so refrigerant leaves the condenser still partly vapor. Negative subcooling means flash gas reaching the metering device. Cross-check superheat: high SH + low SC is the textbook undercharge fingerprint. Look for leaks before adding refrigerant under EPA Section 608. Less commonly, low SC can indicate a stuck-open bypass valve or sensor malfunction on commercial equipment.

›What does high subcooling indicate?

High subcooling (over 15°F on a residential system) usually means overcharge — excess refrigerant backs up in the condenser, taking up space normally used by condensing vapor. Less commonly: a dirty condenser coil (heat-transfer fouling raises condenser saturation temperature for the same heat rejection load), restricted condenser airflow, recirculation of hot discharge air over the coil, or non-condensable gases trapped in the system. Cross-check superheat: low SH + high SC is the overcharge fingerprint. Always verify condenser airflow and coil cleanliness before adjusting charge — fouling looks like overcharge.

›Why does subcooling math differ for zeotropic blends?

Zeotropic blends condense across a temperature range at constant pressure. On the liquid line the refrigerant has fully condensed — the relevant saturation boundary is the bubble temperature (below which everything is liquid), not the dew temperature. This calculator uses the bubble curve automatically for zeotropic blends. Using the dew curve for R-407C would overestimate subcooling by approximately 11°F; for R-455A by approximately 22°F.

›Why is TXV charged by subcooling and fixed-orifice by superheat?

A TXV / EEV regulates superheat to its setpoint regardless of how much refrigerant is in the system. So superheat on a TXV system tells you about valve operation, not charge. Subcooling, by contrast, measures how much liquid is backed up in the condenser — directly proportional to charge. Fixed-orifice devices have no feedback control, so superheat varies directly with charge and ambient; it is the right signal to charge against. The ACCA Manual T charging procedure formalizes this: TXV = subcooling, fixed orifice = superheat.

›How does subcooling differ from condenser approach?

Subcooling is T_sat (at discharge pressure) − T_liquid_line, measured on the air side at the condenser exit. Condenser approach is T_sat − T_air_off_condenser (air-cooled) or T_sat − T_leaving_condenser_water (water-cooled), measured on the heat-rejection medium side. Approach tells you how efficiently the condenser is transferring heat; subcooling tells you how much liquid is sitting in the condenser. They're related but separate metrics. A high condenser approach with normal subcooling indicates condenser fouling without overcharge; high subcooling with normal approach indicates overcharge without fouling.

›Why does long line-set installation affect subcooling?

Long liquid line sets — common on mini-splits and multi-zone installations — introduce pressure drop and heat pickup that change subcooling between the outdoor unit and the indoor metering device. Manufacturers commonly recommend higher subcooling at the condenser outlet (e.g., 12-15°F instead of 8-10°F) for line sets over 50 feet to ensure sufficient liquid column reaches the indoor TXV. Always check the manufacturer's line set length adjustment table when commissioning long-line installations.