| name | neqsim-fired-heater-duty-screening |
| version | 0.1.0 |
| description | Educational fired-heater duty and radiant-flux screening using public energy-balance relations (API 560 style). USE WHEN: a task needs a public, screening-level estimate of process duty, fired duty, fuel rate, and average radiant flux for a fired heater before detailed thermal design. |
| last_verified | 2026-06-18 |
| requires | {"python_packages":[],"java_packages":[],"env":[],"network":[]} |
Fired Heater Duty Screening
Use this skill for public, educational fired-heater screening. It estimates the process duty, the fired duty, the fuel-gas rate, and the average radiant-section heat flux using open energy-balance relations so an agent can scope a fired-heater study and check the radiant flux against a public guideline before detailed thermal design.
When to Use
- When a user asks roughly what fired duty and fuel rate a heater needs.
- When an agent needs a quick radiant-flux check to scope a fired-heater study.
- When examples must run without confidential heater designs, vendor data, or company specs.
Inputs
mass_flow: process mass flow in kg/s.
specific_heat: process-fluid specific heat in kJ/(kg K).
inlet_temperature: process inlet temperature in kelvin.
outlet_temperature: process outlet temperature in kelvin.
thermal_efficiency: heater thermal efficiency, default 0.85.
fuel_heating_value: fuel lower heating value in MJ/kg, default 46.0.
radiant_area: radiant-section tube surface area in m2.
allowable_radiant_flux: allowable average radiant flux in kW/m2, default 37.0.
Outputs
process_duty_kw: process absorbed duty Q.
fired_duty_kw: fired duty from the efficiency.
fuel_rate_kg_s: fuel-gas mass rate.
average_radiant_flux_kw_m2: process duty divided by radiant area.
flux_ratio: ratio of average radiant flux to the allowable flux.
fired_heater_warning: ok, watch, or high-flux.
assumptions: public assumptions used by the placeholder model.
Engineering Method
The Python class FiredHeaterDutyModel uses open energy-balance relations only:
- the process duty uses
Q = mass_flow * specific_heat * (T_out - T_in).
- the fired duty uses
Q_fired = Q / thermal_efficiency.
- the fuel rate uses
fuel = Q_fired / fuel_heating_value.
- the average radiant flux uses
Q / radiant_area and is compared to a public guideline.
This is educational and screening-only logic. It uses a constant specific heat, treats all process duty as absorbed in the radiant section for the flux estimate, and does not model convection-section split, tube-wall temperature, flame and bridgewall temperature, draft, or emissions. Typical public average radiant fluxes are about 30 to 37 kW/m2. It is not a replacement for validated fired-heater design (for example API 560) and a qualified review.
Python Usage Pattern
from fired_heater_duty_screening import FiredHeaterDutyModel
model = FiredHeaterDutyModel()
result = model.evaluate(
mass_flow=15.0,
specific_heat=2.4,
inlet_temperature=473.15,
outlet_temperature=623.15,
radiant_area=200.0,
)
print(result.fired_heater_warning)
print(result.fired_duty_kw)
print(result.average_radiant_flux_kw_m2)
Related NeqSim Functionality
For validated fired-heater calculations, redirect to existing NeqSim classes:
neqsim.process.equipment.heatexchanger.FiredHeater — fired-heater equipment model with duty and efficiency.
neqsim.process.equipment.heatexchanger.Heater — generic process heater with duty calculation.
neqsim.process.equipment.powergeneration.HRSG — heat-recovery steam generator for waste-heat duty.
This skill is a public energy-balance triage layer that decides when to invoke those validated heater classes.
Validation Checklist
Common Mistakes
| Symptom | Cause | Fix |
|---|
| Duty too low | Specific heat at wrong temperature | Use an average specific heat over the duty range |
| Flux always high | All duty assigned to radiant section | Split convection and radiant duty in detailed design |
| Fuel rate wrong | Higher heating value used with efficiency on lower basis | Keep the heating value and efficiency on the same basis |
Limitations
- No proprietary heater designs, vendor data, or company specs are included.
- No convection-section split, tube-wall, draft, or emissions modeling is performed.
- A constant specific heat is assumed over the full duty range.
References