Refrigeration Chamber and Defrosting Methods ET 441
Refrigeration Chamber and Defrosting Methods
|Name:||Refrigeration Chamber and Defrosting Methods|
The climate in the cold storage room has a significant effect on the quality of the products stored there. This climate depends on different influences, such as the surface temperature of the evaporators, cold storage room temperature, degree of evaporator icing, quantity and type of refrigerated goods etc.
The icing of the evaporators depends on the evaporator and room temperatures and the quantitiy of humidity introduced by the refrigerated goods. Icing of the evaporators significantly reduces the refrigeration capacity and must therefore be prevented as much as possible by periodic defrosting, i.e. heating the evaporator surfaces. In addition to the periodic defrosting at set times, there is defrosting performed as required by measuring the actual ice coating. The evaporator surface can be heated from the outside by electric heating or from the inside by hot gas directly from the refrigerant compressor.
The trainer features a large refrigeration chamber. Two evaporators allow for an investigation of the effect of different evaporator sizes on the cold storage room climate and the icing. An electric defrost heater and hot gas defrosting are available. The defrost process can be performed as required using a defrost controller or at set intervals using a defrost timer.
Two adjustable heat sources in the refrigeration chamber simulate the cooling load. One of these heat sources generates water steam to simulate the introduction of humidity into the refrigeration chamber.
The measured values can be read on digital displays. At the same time, the measured values can also be transmitted directly to a PC via USB.
The data acquisition software is included. The data acquisition enables e.g. the recording of the defrosting process over time and the online representation of the climate in the refrigeration chamber in the h-x diagram.
The well-structured instructional material sets out the fundamentals and provides a step-by-step guide through the experiments.
- effect of the evaporator size and temperature on the
climate in the refrigeration chamber
- frosting and icing under different operating
- difference between latent and sensitive cooling
- different defrosting methods (electric heater, hot
- configuration of defrost controls such as defrost
timer or defrost controller
* Combined refrigeration and freezing chamber with
temperature and humidity measurement1
* Evaporators of different sizes1
* Different defrosting methods
 2 evaporators, separately switchable via solenoid valves
 electric defrost heater
 hot gas defrosting
 defrost controller and defrost timer
 latent and sensitive cooling load
 evaporation pressure and temperature adjustable
 heat exchanger as superheater and for refrigerant supercooling
 digital display for temperature and humidity in the refrigeration chamber
 GUNT software with online representation of the h-x diagram
 GUNT software for data acquisition via USB under Windows Vista or Windows 7
 refrigerant R134a, CFC-free
Compressor according to CECOMAF
- refrigeration capacity at -5/55°C: 999W
- power consumption: 565W
Latent cooling load: 2x 0...250W
Sensitive cooling load: 1x 0...200W, 1x 0...250W
- pressure: 2x 0...16bar, 1x 0...25bar
- temperature: 7x -50...150°C, 1x -25...125°C
- humidity: 0...100% r.h.
- flow rate: 2...27L/h
Weight: approx. 250kg Required for Operation 230V, 50/60Hz, 1 phase Scope of Delivery 1 trainer
1 GUNT software CD + USB cable
1 set of instructional material Order Details
061.44100 ET 441 Refrigeration Chamber and