Cooling Load Estimation in the Building Based On Heat Sources

Buildings are responsible for at least 40% of energy use in most countries of the world, and for up to 21% of greenhouse gas emissions globally. As this trend continues, real-time building load measurements are essential for dynamic load response control, understanding and improvement of load distributions and profiles, and for climate-responsive design, particularly in commercial buildings. The focus in this paper is the cooling load, which is the rate at which heat must be removed from the controlled zone to maintain the desired temperature. Estimation of maximum cooling load is necessary for sizing of cooling equipments. However, details needed for whole-building simulation are often unreliable or unavailable. As such, simplified models with reasonable accuracy and computational requirements are often used. A cyber-physical system, integration of physical sensors and mathematical model, is proposed in this paper for cooling load estimation. The physical sensor measurements are limited to outside air temperature, solar radiation, room air temperature, and building plug load. Meanwhile, resistance-capacitance (RC) concept was adopted to describe the physics and dynamics of the building envelope for its simplicity and reasonable computational requirements. The cyber-physical system was tested using a typical office having two thermal zones and compared with simulation results from EnergyPlus, a whole building simulation program. Phenomenon such as infiltration, inter-zone air mixing, and air moisture control were not taken into account for the model. Results are presented to determine the accuracy of the simplified model for cooling load estimation.

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Design and Engineering Economic Analysis of a Variable Refrigerant Flow (VRF) and Mini-Split Air Conditioning System

Current Journal of Applied Science and Technology ◽

10.9734/cjast/2019/v34i130111 ◽

2019 ◽

pp. 1-25

Author(s):

A. T. Layeni ◽

C. N. Nwaokocha ◽

S. O. Giwa ◽

M. A. Sulaiman ◽

K. A. Adedeji ◽

...

Keyword(s):

Economic Analysis ◽

Air Conditioning ◽

Net Present Value ◽

Simulation Software ◽

Load Estimation ◽

Cooling Load ◽

Present Value ◽

Present Worth ◽

Split System ◽

Net Present Worth

Design and Engineering Economic Analysis of two widely used Air-Conditioning (AC) systems, Mini-Split and Variable Refrigerant Flow (VRF), in the new Engineering Complex Building under the same indoor and outdoor conditions for an entire year is carried out by using Carrier Hourly Analysis Program software for cooling load estimation, and the Net Present Worth Analysis for Economic Analysis of both systems. Both systems are direct expansion air conditioning systems; hence the cooling load estimation was done using the ASHRAE transfer function method embedded within the Carrier software. Equipment to be used in analysis were selected from the Toshiba selection catalogues (Mini Split system), while that for the VRF system was selected using Toshiba simulation software. The annual energy analysis of both systems indicated that the VRF system will require more energy to run on an annual basis than the Mini Split system. However, the analysis was carried out without considering the part load potential energy savings of the VRF system. Net Present Worth Analysis carried out also favoured the Mini Split system in terms of Net Present Value of the systems. Based on the Engineering Economic Analysis carried out on the two systems, the overall Net Present Value for the VRF system is N77,891,808.66, while that of the Mini-Split system is N46,641,828.74. This result shows that the VRF system has a higher cost implication than the Mini-Split system. Hence, in terms of cost, the Mini-Split system is a more viable option.

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Numerical Investigation on Energy Analysis for the Heating and Cooling Load Estimation of a Rooftop Greenhouse Integrated with a Supermarket

Korean Journal of Air-Conditioning and Refrigeration Engineering ◽

10.6110/kjacr.2019.31.11.528 ◽

2019 ◽

Vol 31 (11) ◽

pp. 528-537

Author(s):

Taehoon Kim ◽

Yong-Shik Han ◽

Byung-Il Choi ◽

Kyu Hyung Do

Keyword(s):

Numerical Investigation ◽

Energy Analysis ◽

Load Estimation ◽

Cooling Load ◽

Heating And Cooling ◽

Heating And Cooling Load

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The influence of heat source distribution on the space cooling load oriented to local thermal requirements

Indoor and Built Environment ◽

10.1177/1420326x19891632 ◽

2019 ◽

pp. 1420326X1989163

Author(s):

Chao Liang ◽

Arsen Krikor Melikov ◽

Xianting Li

Keyword(s):

Heat Source ◽

Source Distribution ◽

Thermal Plume ◽

Cooling Load ◽

Heat Sources ◽

Local Cooling ◽

Thermal Requirements ◽

Space Cooling ◽

Airflow Field ◽

Heat Source Distribution

Existing studies have shown that the space cooling load oriented to local thermal requirements is significantly influenced by different heat source distributions. However, numerical methods have been mainly used in the analysis based on a fixed airflow field and ignoring the thermal plume. Here, an experiment in a chamber with mixing ventilation was conducted. The heat sources were simulated by metal barrels and an oil-filled radiator, 13 types of heat source distributions were designed and the local cooling load (LCL) was used as the evaluation index. The results show that (1) the LCL is equal to the total amount of heat sources at the steady state in a room with mixing ventilation only if the heat sources are also distributed uniformly; (2) the LCL decreases with a decrease in the intensity of heat sources, achieving a decrease rate of 47.4%–70.8% in the experiment with different intensities; (3) the LCL is 9.2%–22.3% lower than the total amount of heat sources when these are located near the exhaust diffuser or far away from the target zone; (4) owing to its smaller surface area, the LCL with an oil-filled radiator is 7% lower than that with five metal barrels.

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