Types of air conditioner condenserAC condenser units are grouped according to how it rejects the heat to the medium (surroundHere are a few condensers units. • Air cooled condenser• Earth cooled condenser (Geothermal Heat Pumps)• Water cooled condenser• Combination of air and water cooled condenser (Evaporative condensers) Air cooled condensers are mostly used in a residential air conditioner system and commercial air conditioning unit. The Air Cooled CondenserThe air conditioner parts that are located beside residential are an air cooled condenser. Air cooled condenser use outdoor air as a place to reject the heat absorbs by the indoor air conditioner units. These are the part that help with the condenser heat rejection: • Condenser fan blade• Condenser motor • Condenser coils• Air conditioner compressor is within the condenser unit, but it does not help with heat rejection! condenser fan is mounted with the air cooled condenser. fan primary purpose is to increase condenser unit’s capacity to reject

Air cooled condenser come into two types: • Fin and tube condensers• Plate condensersThe Water Cooled Condensers The water cooled condensers reject the heat absorbs by air conditioner system to the water. The water has to be clean, noncorrosive, and at certain temperature. This water has to be treating to prevent pitting corrosive, algae, scale, chalky, and mineral deposits. Even though, water cooled condenser require regular maintenance, it is more efficient than air cooled condenser, and it operates at much lower condensing temperature.Types of water cooled condensers: • Tube in tube• Shell and coil• Shell and tubeWhat are air conditioner condensers? Air conditioner condensers are a heat exchanger device; it has a similar operation principle to the evaporator. The condenser rejects heat from the air conditioner system to surrounding air (medium). While the evaporator absorbed heat from space that needs to be cool. In our case, it is from indoor air. The condenser units take in high-pressure, high temperature refrigerant gas from the compressor and turn it into high-pressure, high temperature liquid refrigerant.

How does an ac condenser change refrigerant gas to liquid refrigerant? Here how it does that.Air conditioner condensing unit work by turning vapor refrigerant to liquid refrigerant. There are three important steps that will happen to the refrigerant as it passes through the condensing unit. How does air conditioner condensers make?Here is Trane condensing unit video: Make sure to press the Play button in the player controls to watch it. The refrigeration process to how air conditioner condensing unit workRefrigeration is the process of removing heat from one area, where it is not wanted, to an area where it is not important. window ac unit best priceFor the refrigeration process to work heat has to flow from one area to another. ac unit motor replacementHere is a step to how heat will be transfer from AC evaporator coils to AC condensing unit. ac window units reviews

In this discussion, the air conditioner condensers will transfer heat toFor heat to flow, one of the areas has to be at aThis is because heat always flows from a high intensity to a low intensity. The air conditioner condensers reject heat from the refrigeration system absorbed at the evaporator and also heat of compression from the compressor. refrigerant that must reject its heat to the outside medium (air thatTherefore, the refrigerant temperature in the condenser units must be higher than the surrounding air. take thermodynamic classes, our professor expect us to understand it . I will explain how air conditioner condensing unit work from PH charts. The condenser units receive the hot vapor refrigerant after it leaves the compressor through the short refrigeration line between the compressor and the condenser unit. This refrigerant line has known as the hot gas line or discharge line. Point 2 on the pH diagram showed the hot vapor from the compressor is forced into the top of the condenser coils.

The vapor refrigerant is being pushed at high speed and high temperature to the condenser units. The vapor does not corresponding to the saturation pressure/temperature relationship because the vapor contains superheat added by the evaporator and the heat of compression process. This process is shown between points 2 to 3. The vapor entering the condenser is so hot compared to the surrounding air that a heat exchange begins to occur immediately after the vapor leaves the discharge area of the compressor. Generally, the air will be 90-105°F lower than the superheated vapor leaving the compressor.The first heat exchange removes sensible heat from the superheated vapor bringing the refrigerant vapor to the saturation point, point 2 to 3 on the pH chart. As the refrigerant vapor continues through the condenser latent heat is removed. This process is shown between points 3 and 4. The removal of latent heat causes a change of state to take place. The vapor will begins to change to liquid from this point on until it reaches a point nears the end of the condenser units where the entire vapor has changed to liquid.

This is known as the saturated liquid point, point 4 on the pH chart. As the air conditioner refrigerant flows through the last few rows of the condenser units additional sensible heat is removed, lowering the refrigerant temperature below its liquid saturation point. This called subcooling and represented by the line from point 4 to 5 on the pH chart. There must be enough air flowing across the AC condenser, for vapor refrigerant to change to liquid. The air flowing across the condenser unit has to be correct. This airflow has to be at low enough temperature, so it could absorb heat from the condenser unit. The entire vapor refrigerant has to turn liquid before it leaves the condenser units. Remember, the air conditioner condensers:This is how air conditioner condensers work in HVAC units. Read other central air conditioner parts.Architectural Association School of Architecture Spatial Performance & Design History & Critical Thinking Architecture and Urban Design (Projective Cities)

Professional Practice and Practical Experience (ARB/RIBA Part 3) History & Theory Studies MPhil in Media Practices Autumn Semester ProgrammeLittle ArchitectMakeLabPowerstockRobotic FabricationsSpring Semester programmeSummer DLABSummer Schoolt-sa forum x AA BaliBangkokBeijingBengaluruCebuChengduHong KongKoshirakura/Tokyo PunePyongyangSeoulShanghaiUnknown FieldsVietnamWuhanXixinan AmazonBuenos AiresGuatemalaHaiti FallHaiti SummerHawaiiLas PozasLos AngelesMexico CitySan FranciscoSantiagoSão Paulo Material Life II: Transformative Envelope Intermediate 7 works along the notion of applied research, engaging directly with the materiality of architecture and the practical application of science and technology in the design process. Innovations in material science, manufacturing technology and computation offer new ways of organising structures and simulating their performative output within dynamic environments. We continue our research on understanding the building envelope as the

catalyst for organisational, material, economic and representational aspects Focusing on the transformative qualities of matter and, in particular, the integration into the building envelope of movement and motion control, the unit will develop both active and passive systems to address the growing need for a resilient built environment. Form can be shaped by the interaction of an envelope with its environment. While its geometry is described by Cartesian coordinates, the thermo-fluid environment for which it is designed contributes to its shape. A boat hull, for example, does not change in shape but its topology is designed to address a multiplicity of vectors that determine its movement in space. Similarly, the architectural envelope can be designed to respond to specific dynamic scenarios - whether the building remains static or its component parts are in motion. The envelope seeks the boundary of architecture, whether this is defined by its interior organisation or by the nature

of the surrounding environment. We will test the transformational capacity of building envelopes through a series of prototypical projects addressing the housing shortage in the SanIn Silicon Valley 90,000 new units of affordable housing will have to be built over the next 20 years to meet growing demand. develop new functional and flexible urban typologies to address this challenge. We will test ideas in a workshop environment, through the developmentWe will experiment with manufacturing processes, material and computation in order to create new functional, resilient and Marco Vanucci is founding director of OPENSYSTEMS Architecture. He studied architecture in Italy and the UK and worked for Zaha Hadid Architects and AKTII, where he was involved in many seminal projects at the intersection of computational design, engineering and fabrication. He has lectured internationally, led workshops and taught at KTH in Stockholm. His works have been published and exhibited throughout Europe and North America.