
Explore the basics of cooling load concepts, emphasizing energy analysis, data accuracy, and practical calculations for equipment selection and system design.
Analyze zone, space, and system concepts in cooling load estimation, and compare thermostat-based control with targeted cooling within interior spaces to optimize performance.
Explore cooling load estimation methods using HAP 5.1, focusing on accuracy, load factors, heat balance programs, transfer functions, and radiant time-series analysis to predict cooling requirements.
Explore the principles of heat transfer, focusing on conduction, convection, and radiation, and see how these mechanisms inform cooling load estimation using HAP 5.1.
Learn the fundamentals of the psychometric chart, including dry bulb temperature, dew point, and relative humidity, for understanding cooling load estimation.
Explore the psychrometric properties of air, including dry-bulb temperature, dew point, relative humidity, and humidity ratio, and apply them to cooling load estimation using a psychrometric chart.
Explore atmospheric clearance number, average ground reflectance, and soil conductivity as key inputs in cooling load estimation with hap 5.1.
Apply hap 5.1 to cooling load estimation by building a model and using energy simulations to address design temperatures and related design challenges.
Investigate how schedules, lighting, and thermostat controls affect cooling load in building systems, and apply energy analysis within the HAP 5.1 framework to optimize performance.
Analyze how windows and doors influence cooling load estimation using hap 5.1, focusing on glazing types, shading coefficient, and u-value to guide material recommendations.
Examine space properties for cooling load estimation, focusing on ventilation requirements and air quality. Identify minimum litres per second per square metre fresh air rates guiding building design.
Explore space properties internal elements that drive cooling load, including overhead and task lighting, venting, surface types, and free hanging configurations within nonresidential spaces.
Examine space properties of walls and roofs, including skylight design and orientation, and assess how gross area, shading coefficient, and U-values affect cooling loads.
Review the project by examining the diverse topics and discussions in the transcript, noting steps and considerations for applying cooling load estimation concepts in Arabic.
Start a new cooling load estimation project using hap 5.1 by leveraging weather data and project libraries to explore window glazing, roof configurations, and cooling strategies.
Define first floor spaces for cooling load estimation using HAP 5.1, addressing space types, ceiling height, ventilation, and interior partitions in non-residential settings.
Explore dx-systems on hap 5.1, covering terminal and package units, zone sizing, fresh air and doas integration, and energy-based cooling load estimation for efficient building comfort.
Explore chilled water systems and chillers, including refrigeration cycles, compressors, condensers, evaporators, expansion devices, and cooling towers, with comparisons of air- and water-cooled configurations.
Explore air terminal units within heating, ventilation, and air conditioning systems, including filters, humidifiers, dehumidifiers, heat recovery, and fresh air handling to optimize cooling loads.
Design an FCU system on HAP 5.1, coordinating chilled water and groundwater cooling, induction cooling, and direct ventilation with thermostat control, sizing data, and delta t-based supply temperatures.
Create an AHU system on HAP 5.1 to design and compare multi-zone cooling using variable air volume, zone sensors, and thermostats for fresh air and efficient cooling.
Explore AHU system components in hap 5.1, including coils, fans, ducts, and heat recovery, and learn how ventilation, dehumidification, and sensible heat recovery shape cooling loads and the system load.
Create an ahu system on hap 5.1 by using zone and sizing data to estimate cooling loads, assess humidity ratio, and configure coils, steam injection, water supply, and controller settings.
Hello Every one ,
The importance of accurate cooling load calculation is very essential to make a good HVAC design ,choosing the right systems ,suitable selection of different equipment and even for building energy consumption after stating , we will start this course by learning the fundamental of cooling load , the used units , different types of loads and we will study the importance of psychrometric chart learning the different parameters and process of air .
We will also emphasize on using Hourly analysis program HAP 5.1 the latest version of carrier program , we will learn how to define the weather , Project libraries , Space properties , System Properties ,Plant properties and how to generate the different types of reports and how to read this reports .
Choosing the suitable system is very important , so we will learn the different types of Dx-Systems , chilled water system ,why we use refrigerant , the main components of Vapor compression cycle , the different types of chillers , air cooled vs water cooled , absorption chillers , cooling tower components , Pumps , and different types of terminal coils (Fan Coil Unit & Air handling Unit ).
objectives :
1. The importance of accurate Load Estimation.
2. The Main Load Components (External/Internal/System).
3. The Difference between Zone, Space and System.
4. Principles of heat transfer.
5. How to read the Psychometric Chart.
6. Introduction to HAP Program.
7. How to choose the weather conditions.
8. How to build the project libraries.
9. How to create the spaces and define the different loads.
10. Introduction to HVAC systems (DX & Chilled water) .
11. Different types of DX Systems (Split units, Package Units, VRF ,…).
12. The main components of Chilled Water Systems (Chiller ,cooling tower ,Pumps, AHU,FCU ).
13. How to create the different types of systems on HAP Program.
14. How to create Chiller plant on HAP Program.
15. How to generate reports from HAP program.