A Hybrid Dynamic Model for the Thermal Compressor Heat Pump and Validation with Experimental Data

[en] Thermally driven heat pumps primarily use thermal energy to drive a compression cycle. The thermal energy can be waste heat, natural-gas combustion, or solar, helping increase efficiency and reduce greenhouse-gas emissions. We study a thermal compressor heat pump (TCHP) in which Stirling-type thermal compressors (TCs) are heat-driven rather than electrically driven, delivering a nominal heat capacity of 8 kW with CO2 as the refrigerant. Like any vapor compression cycle (VCC), a TCHP requires a dynamic model for control and optimization; its predictive reliability must be validated on experimental data. We therefore describe the test bench and performance expressions, collect steady-state and transient datasets, and derive a hybrid dynamic model: finite-volume (FV) differential equations for slow components and quasi-static submodels (linear regressions and correlations) for fast elements. Validation shows good agreement with experiments. Validation—On 15 steady-state operating points, the model reproduces pressures within ∼1 bar mean absolute error (MAE) and system-level performance (total recovered heat, COPth) within ∼6% mean absolute percentage error (MAPE), with R2≳0.8; component heat-rate predictions are within ∼20% MAPE. Under transient step tests on expansion valve openings and burner fan speed, the thermal COP and total recovered heat track within 4% MAPE (up to R2=0.96), pressures within 1.5 bar MAE, and the evaporator heat rate within 14–22% MAPE.

Disciplines :

Energy

Author, co-author :

Salame, Ali Al Hadi ; Université de Liège - ULiège > Aérospatiale et Mécanique (A&M)

Lemort, Vincent ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Thermodynamique appliquée

Dufour, Pascal; UCBL - Université Claude Bernard. Lyon 1

Nadri, Madiha; UCBL - Université Claude Bernard. Lyon 1

Language :

English

Title :

A Hybrid Dynamic Model for the Thermal Compressor Heat Pump and Validation with Experimental Data

Publication date :

2026

Journal title :

Energies

ISSN :

1996-1073

Publisher :

MDPI, Switzerland

Volume :

19(1)

Issue :

159

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 19 November 2025

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