Database with efficiency parameters from public Heatpump Keymark datasets as well as parameter-sets and functions in order to simulate heat pumps (manufacturer+model or generic type)
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.7...v1.9
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.7...v1.8
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
p_th_min
to add a minimum thermal power output in hplib.sumulate()
.Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.5...v1.7
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
p_th_min
to add a minimum thermal power output in hplib.sumulate()
.Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.5...v1.6
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.4...v1.5
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.3...v1.4
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
For speeding up simulations that use hplib in for loops
or single time steps iterations
a new HeatPump
class was introduced including a optimized simulate()
method. Further more, the hplib is now also capable of simulate the thermal cooling power and EER for heat pumps of group id 1 (air/water | regulated).
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.2...v1.3
Full Changelog: https://github.com/RE-Lab-Projects/hplib/compare/v1.0...v1.2
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
If you're interested in how the database and parameters were calclulated, have a look into the Documentation HTML or Jupyter-Notebook. There you also find a simulation examples and a validation.
Download or clone repository:
git clone https://github.com/RE-Lab-Projects/hplib.git
Create the environment:
conda env create --name hplib --file requirements.txt
Create some code with import hplib
and use the included functions load_database
, get_parameters
and simulate
.
The hplib_database.csv contains the following number of heat pump models, sorted by Group ID
Group 1, Outdoor Air / Water, Regulated (366 Models)
Group 2, Brine / Water, Regulated (54 Models)
Group 3, Water / Water, Regulated (0 Models)
Group 4, Outdoor Air / Water, On-Off (23 Models)
Group 5, Brine / Water, On-Off (53 Models)
Group 6, Water / Water, On-Off (10 Models)
All resulting database CSV file are under .
The following columns are available for every heat pump of this library
Manufacturer | Name of the manufacturer
Model | Name of the heat pump model
Date | heat pump certification date
Type | Type of heat pump model
Subtype | Subtype of heat pump model
Group ID | ID for combination of type and subtype
Refrigerant | Refrigerant Type
Mass of Refrigerant [kg]| Mass of Refrigerant
SPL indoor [dBA]| Sound emissions indoor
SPL outdoor [dBA]| Sound emissions outdoor
PSB [W] | Eletrical power consumption, standby mode
Climate | Climate definition for set points, which were used for parameter identification |
P_el_ref [W]| Electrical power at -7°C / 52°C
P_th_ref [W]| Thermal power at -7°C / 52°C
p1-p4_P_th | Fit-Parameters for thermal power
p1-p4_P_el | Fit-Parameters for electricl power
p1-p4_COP | Fit-Parameters for COP
MAPE_P_el | mean absolute percentage error for electrical input power (simulation vs. measurement)
MAPE_COP | mean absolute percentage error for thermal input power (simulation vs. measurement)
MAPE_P_th | mean absolute percentage error for coefficient of performance (simulation vs. measurement)
The European Heat Pump Association (EHPA) hosts a website with the results of laboratory measurements from the keymark certification process. For every heat pump model a pdf file can be downloaded from https://keymark.eu/en/products/heatpumps/certified-products.
This repository is based on all pdf files that were download for every manufacturer on 2021-03-12.
Repository with code to
For the simulation, it is possible to calculate outputs of a specific manufacturer + model or alternatively for one of 6 different generic heat pump types.
If you're interested in how the database and parameters were calclulated, have a look into the Documentation HTML or Jupyter-Notebook. There you also find a simulation examples and a validation.
Download or clone repository:
git clone https://github.com/RE-Lab-Projects/hplib.git
Create the environment:
conda env create --name hplib --file requirements.txt
Create some code with import hplib
and use the included functions load_database
, get_parameters
and simulate
.
The hplib_database.csv contains the following number of heat pump models, sorted by Group ID
Group 1, Outdoor Air / Water, Regulated (366 Models)
Group 2, Brine / Water, Regulated (54 Models)
Group 3, Water / Water, Regulated (0 Models)
Group 4, Outdoor Air / Water, On-Off (23 Models)
Group 5, Brine / Water, On-Off (53 Models)
Group 6, Water / Water, On-Off (10 Models)
All resulting database CSV file are under .
The following columns are available for every heat pump of this library
Manufacturer | Name of the manufacturer
Model | Name of the heat pump model
Date | heat pump certification date
Type | Type of heat pump model
Subtype | Subtype of heat pump model
Group ID | ID for combination of type and subtype
Refrigerant | Refrigerant Type
Mass of Refrigerant [kg]| Mass of Refrigerant
SPL indoor [dBA]| Sound emissions indoor
SPL outdoor [dBA]| Sound emissions outdoor
PSB [W] | Eletrical power consumption, standby mode
Climate | Climate definition for set points, which were used for parameter identification |
P_el_ref [W]| Electrical power at -7°C / 52°C
P_th_ref [W]| Thermal power at -7°C / 52°C
p1-p4_P_th | Fit-Parameters for thermal power
p1-p4_P_el | Fit-Parameters for electricl power
p1-p4_COP | Fit-Parameters for COP
MAPE_P_el | mean absolute percentage error for electrical input power (simulation vs. measurement)
MAPE_COP | mean absolute percentage error for thermal input power (simulation vs. measurement)
MAPE_P_th | mean absolute percentage error for coefficient of performance (simulation vs. measurement)
The European Heat Pump Association (EHPA) hosts a website with the results of laboratory measurements from the keymark certification process. For every heat pump model a pdf file can be downloaded from https://keymark.eu/en/products/heatpumps/certified-products.
This repository is based on all pdf files that were download for every manufacturer on 2021-03-12.