Friday, February 25, 2022

Iris Publishers-Open access Journal of Current Trends in Clinical & Medical Sciences | Active Filtering and Exchange of Indoor Air by Means of Mobile Air Conditioners to Avoid Infection by The SARS Cov-2 Virus

 


Authored by Sebastian König* 

Introduction

In not actively ventilated rooms such as in schools, air exchange is insufficient, particularly during win- ter. Under the presence of COVID-19 or to reduce the CO2 concentration, the air must be filtered and refreshed as well as possible. A tracer clearance experiment using a mobile air conditioner e.g. from KRONE Kälte + Klima VertriebsmbH Germany is supposed to determine to what extent. In Szabadi [1]. the air exchange rate [n] = 1/h is introduced as a measure of air exchange. The exhaust volume flow [dV/dt] ⩒ = m3/h is related to room volume [V] = m3. The air exchange rate n is a multiple of the room volume. Reference values are n = 3/h <= n <= 6/h. The air conditioner in (Figure 1) comprises an air recirculation (5) and an active air exchange (6). The recirculation may also filter and cool the air. Here, the air filter rate [f] = 1/h serves as a measure. Both measures must be considered according to [1].

Setup

A mobile air conditioner (1) in (Figure 2) actively recirculates (2) and refreshes (3) the air of the room. A ventilator (4) supports recirculation. The recirculation of air (5) in (Figure 1) also cools an dehumidifies and filters the air. The second air exchange (6) suck in the room air and blows it out of the window. The air conditioner

GREE GPC-12-AL-R290 [2] comes with a recirculation volume flow of ⩒ = 360 m3/h and is optimized for rooms up to floor area of 22m2an air exchange rate of n ≈ 16/h. The conducted measurements show effectiveness also in bigger rooms. Disco fog (EUROLITE smoke fluid -X EXTREM A2) served as a tracer replacing the aerosol. The relative fog density is measured indirectly via relative light transmission T = 0T=0%...100% alternativly 0%<=T<=100% with measuring instrument TRDA 2.0 [3]. In a seminar room of V = 220 m³ Figure 3, an active operating mode without refrigeration and without dehumidification is used (Figure 1& 2).

Result

Figure 4 shows the plot of the tracer clearance process by relative light transmission as a function of 83 minutes the fog is removed completely whence n = 360 m3/h /220 m3 = 1, 6/h. After t < 10 s without fog (which is T˳ = 100%) the room is filled with fog. The light transmission goes down Figure 4 shows the plot of the tracer clearance process by relative light transmission as a function of two T < 10%. At the same time the air filter rate f = 2/h has effect. As example for lecture rooms, n ≥ 8/h is required. This is accomplished by stationary air conditioners. the step response of a simple mathematical model with just one-time constant τ and a normalized light transmission T˳= 100% is plotted in red in Figure.

The units are [t] = min, [τ] = min and [T0] = 100%. The time constant τ estimated by the room volume V = 220 m³ and dV/dt = V,dot = 360 m³/h = 6 m³ / min as τ ≈ 37 min. The Error of the model is.... -10% in practice, clearance is done faster than estimated. We recommend the use of a mobile air conditioner. During the warm seson, the mobile air conditioner may additionally refrigerate. With an additional cabin filter [5] the filtering effect can be improved (Figure 3 & 4).

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