Outdoor Water Cooled Chiller

Kontaktieren Sie uns noch heute für die perfekte Lösung zur Temperaturkontrolle

What is an outdoor water cooled chiller?

An outdoor water cooled chiller is one of those water chillers that removes heat from the water used in projects and industrial structures and puts the water back into the running cycle. In effect, a chiller moves heat from a space that requires temperature control to another space. Therefore, the chiller is not a means of generating cold, but a means of dissipating heat, whose task is to facilitate the transfer of unwanted and undesired heat caused by activity to places outside the system.

Cooling towers are specially designed for outdoor water cooled chillers. Because the condenser of a water-cooled chiller uses water as a stimulus and cooling material. The efficiency of a water-cooled chiller increases because wet surfaces are more successful at transferring heat and can do compression work at wetter temperatures.

How does outdoor water cooled chiller work?

Water-cooled chillers come into play during the evaporation process, the water and gas produced by the machine are taken to the evaporator and collect all the unwanted heat on the way and then return to the evaporator and store the obtained heat energy. After that, the refrigerant collects this heat and mobilizes it into the condensate, that is, the condenser sends all the collected heat to the cooling tower, and finally the hot air will pass through the cooling coil and dissipate the heat to the atmosphere.

The first stage:

The starting point of this cycle is where the water from the production process enters the evaporator and enters the cooling cycle.

During this part of the cycle, the heat absorbed by the refrigerant first appears in the form of a phase change from liquid to gas phase. As the refrigerant absorbs heat from the water, the temperature of the environment in contact with this part drops, so the water leaves at a lower temperature. This water enters the fan coil and carries the cool air to the desired space.

In fact, the evaporator is a place that, in addition to the current cycle, participates in another cycle, which is located between the evaporator and the water outlet of the cooling device. In fact, hot water enters the chiller evaporator, which cools it and then pumps it throughout the building to where it is needed.

second stage:

The gaseous refrigerant reaches the gas phase in the pre-liquid state and then enters the compressor. In the compressor, the gas condenses and the temperature and pressure increase so that it can enter the next high-pressure stage. The rise in pressure and temperature as it leaves the compressor is important because the refrigerant needs to release heat from inside the condenser, so it must carry enough heat to the condenser.

Another key function of the compressor is to draw refrigerant into the evaporator at the right time, keeping the pressure within the evaporator high enough to absorb the heat again.

The third phase:

The high-temperature gas enters the condenser, where the gaseous refrigerant is converted into a saturated, high-pressure liquid. This is a constant pressure process.

Since the condenser exists in another loop between the cooling towers, the water enters the cooling tower after the temperature rises. Because the main task of the cooling tower in a water-cooled chiller is to cool the consumed water, and the condenser uses this water as its driving material.

Where the excess heat of the water disappears and the water temperature returns to the desired low temperature. The heating process we mentioned earlier occurs in the condenser, releasing the gaseous refrigerant from the heat itself, which is the source of heat in question and needs to be eliminated by the cooling tower. In this way, the water entering the cooling tower from the condenser comes into contact with the air flow, transfers heat to the air, and then returns to the condenser.

The fourth stage:

The expansion valve is the last stage of the refrigerant and the refrigerant in the expansion valve undergoes these processes causing the refrigerant to become a mixture of liquid and gas and the same compounds re-enter the evaporator to resume the cycle.

E-Mail: info@lneya.com    WeChat ID: +8615251628237    WhatsApp: +86 17851209193

Präzisionskältemaschinen / Kleinkältemaschinen

(Benutzerdefinierte Designs)

Die Kältemaschine kann in verschiedenen Industrien und Labors eingesetzt werden und unterstützt kundenspezifische Designs.

Rückkühler

(Benutzerdefinierte Designs)

Unser Rückkühler arbeitet mit Niedertemperatur-Kältetechnik, die Temperatur beträgt bis zu -120℃, und verschiedene Zubehörteile sind anpassbar.

Niedertemperatur-Kühlgeräte

(Benutzerdefinierte Designs)

Wir haben uns auf die Herstellung von Niedertemperaturkältemaschinen mit einem Temperaturregelbereich von bis zu -150°C spezialisiert, die den Kühlbedarf verschiedener Branchen decken.

Chillers for Automotive Test

(Benutzerdefinierte Designs)

Temperatursimulation für die Qualitätsprüfung von Fahrzeugen: Prüfung der Batterielebensdauer, Prüfstand für Einspritzdüsen/Motoren, Airbag-Prüfung, Komponentenprüfstand, usw.

Chillers for Semiconductor

(Benutzerdefinierte Designs)

Geeignet für die präzise Temperaturkontrolle von elektronischen Bauteilen. Bei der Herstellung von elektronischen Halbleiterkomponenten für raue Umgebungen umfassen die Phasen der IC-Gehäusemontage sowie der Entwicklungs- und Produktionstests auch elektronische Wärmetests und andere Simulationen von Umwelttests.

Flüssigkeitskühlung für Batterie-Energiespeichersysteme

(Benutzerdefinierte Designs)

Baureihe ZLFQ

(Benutzerdefinierte Designs)

Kühlmittelverteilereinheit

Flüssigkeitskühlgeräte eignen sich für die Prüfung von Halbleitern, die Prüfung elektronischer Geräte bei konstanter Temperatur, die Kühlung der Serverinfrastruktur und andere Orte, an denen die Temperatur von Flüssigkeiten kontrolliert wird.

MD-Thermofutter-Serie

(Benutzerdefinierte Designs)

Es wird für die Prüfung von HF-Bauteilen und Leistungsbauteilen mit hoher Dichte (IGBTs und MOSFETs) verwendet und kann auch für die schnelle Kühlung von flachen Laborplatten (Plasma, biologische Produkte, Batterien) usw. eingesetzt werden.

Schrauben-Kühlmaschinen (Benutzerdefinierte Designs)

Niedertemperatur-Schraubenkühlmaschinen und Raumtemperatur-Schraubenkühlmaschinen