CFD Simulation of Industrial Building HVAC System

PROJECT DETAILS

  • Client: NORVENTO
  • Date: 2023
  • Technology: HVAC Analysis. CFD Simulation and Optimisation of natural convection, forced convection and underfloor heating systems.

INTRODUCTION

This project carried out by ICEMM aims to carry out a comparative analysis of five different HVAC systems for a large industrial building. CFD simulation will be used for this purpose. In the building there are thermal requirements both for human comfort and for the process that is carried out inside, which requires some materials whose temperature must be maintained above a minimum value. Due to confidentiality issues, the results maps provided will simply be examples without quantitative data or relation with the real cases studied.

The ventilation and air conditioning simulations are carried out by modelling the walls with the enclosures designed for the building. Also, the air infiltrations are adjusted in the model to take into account this additional thermal load that will exist in the real building. These conditions will be the same in all the thermal analyses in order to have a real comparison between the systems. The alternatives that are compared in the HVAC simulations are:

  • Fan heater system
  • Nozzle system
  • Underfloor heating system
  • Radiant ceiling system
  • Radiant wall system

 

The study was carried out with MSC Cradle‘s ScStream software.

CFD MODEL DEFINITION AND PRE-DIMENSIONING

In the first phase, an analytical calculation is made on the basis of the thermal load booklet. In this way, an initial size is assigned to the air-conditioning systems. This pre-design is done considering the requirements and restrictions of the client and taking the data of the equipment from specialised suppliers.

In this way, an estimate is obtained of the number of fan heaters and nozzles to be installed in each proposal, and the power that the radiant elements must be able to provide in order to achieve the target temperature.

In parallel to the pre-dimensioning, a CAD model is created containing the main geometry of the building, considering the external and internal elements that are of interest. A study of the infiltrations predicted by the CFD model is also carried out so that their effect on the model is adjusted to reality.

Starting from this base model, the five models corresponding to each air-conditioning system to be simulated are generated. The following images show the geometry of the building and an interior view with the preliminary nozzle system modelled.

Geometría básica de la nave analizada mediante simulación HVAC

 

CFD SIMULATION OF HVAC SYSTEMS

In the first stage of simulation, we start from the pre-design and calculate the five proposed HVAC systems. This type of analysis allows us to obtain maps of operating temperature, air speed, surface temperature and PMV (Predicted Mean Vote) among many other results.

The CFD simulations take into account the effects of heat transfer by convection, conduction (heat losses to the ground, for example) and radiation, which are particularly relevant in some of the proposed systems. They also resolve the fluid velocity fields, so that thermal comfort can be assessed comprehensively considering the effects of air currents.

To correctly simulate thermal effects, the meshing and physical models must be appropriate for the problem under consideration. In this study, grids of between 15 and 25 million elements (cells) are used to capture the phenomena of interest.

In this first stage, it is found that some of the proposed systems are far from giving satisfactory results. This means that in the subsequent optimisation stage, only the systems that have given the most favourable results are compared. The following image shows the operating temperature results in a vertical slice of one of the systems analysed.

Mapa de temperaturas en la nave como resultado de la simulación CFD de la climatización

And in the next one you can see the PMV map calculated with the thermal insulation values by clothing and physical activity expected for the workers in the building. This is given in a horizontal cut at the usual working height.

Mapa de PMV en la nave como resultado de la simulación CFD de la climatización

SYSTEM OPTIMISATION

In the initial analyses, it is observed that convective systems can have an efficiency problem caused by air stratification in the enclosure, a common phenomenon in high-rise halls. This means that the hot air accumulates in the upper part of the building and leaves the occupied area at a lower temperature than expected.

To prevent this situation, the addition of destratifier fans in the fan heater system and an increase of the discharge velocity in the case of nozzles is being considered. Some examples of destratifiers are shown in the following picture.

Ventiladores de destratificación simulados mediante CFD en la nave

The HVAC simulation results show that the use of destratifier fans has a significant impact on temperature only if the drive is at high speed. However, this generates high velocity zones that penalise thermal comfort. These effects are amplified by some corridors created by the fixed elements of the building, as can be seen in the following image.

Mapa de velocidades en la nave al colocar los destratificadores a su máxima velocidad

 

For radiant systems, it was decided to study other external conditions, simulating a less unfavourable case of temperature outside the building. In this way, the performance of the system can be better assessed with additional information.

The optimised solution that is finally chosen shows very satisfactory results in terms of effectiveness and efficiency. In the following images you can see the operational temperature maps in a vertical slice and PMV in a plan view obtained with this system.

Mapa de temperaturas en la nave como resultado de la simulación HVAC optimizada de la climatización
Mapa de PMV en la nave como resultado de la simulación HVAC optimizada de la climatización

 

THERMAL COMFORT STUDY – HUMAN THERMOREGULATION MODELS

As a final stage of the air conditioning study, a series of simulations including a human thermoregulation model are carried out. These are chosen on the basis of the alternatives that have proved to be the most advantageous in terms of thermal comfort and energy efficiency.

The model used, known as JOS2, simulates the thermal behaviour of the human body and its interaction with the environment. It takes into account factors such as clothing, age and level of physical activity. This makes it possible to predict thermal comfort in detail in combination with CFD simulation. A schematic of how the model works is shown in the image, taken from the website of the software used in the analyses.

Esquema del modelo de termorregulación humana incluido en Cradle

 

For the study, a number of dummies are placed at different positions on the ship and the model is simulated as a whole. Three examples of skin temperature results in different scenarios are shown below. This data is a good indicator of the perceived thermal sensation and the actual thermal comfort of the occupants.
Distribución de temperaturas en la piel de las personas simuladas con el modelo JOS2 y CFD en el estudio de la climatización

CATEGORIES:

CFD - DEM,Civil Engineering and Architecture,Industry

Year:

2023

Country:

España