SU1413384A1 - Air cooler - Google Patents

Abstract

The invention relates to refrigeration process equipment, namely, air coolers for climatic and refrigeration chambers, and allows for reducing the energy consumption of the device by allowing more uniform distribution and distribution over its heat transfer section. Air with a fan 4 through the inlet pipe 2 enters the inlet the first is a tenlo of the exchange section 5, and then to subsequent sections 6, 7, 8 and 9. In the initial period of operation of the air cooler, the air flow rises, 2 Si mainly through the heat exchange sections 5, 6, 7, 8 9, as they are hydro soprotiv ix less hydraulic resistance and backlash. and distance s. At the entrance to the first section 5, the difference in moisture content in the air and near the heat exchange surface is greatest, which determines the intensive frost formation on it. As the annulus and intercostal spaces become clogged with frost of the first section 5, the air flow is redistributed due to the increase in the hydroresistance of this section. This increases the proportion of the air flow passing through the gap CL, with some of the moisture flowing into the subsequent sections 6, 7, 8 and 9, which increases the proportion of wet load on them. As further deposition does not occur in the heat exchange section 6, the air flow passing through it also redistributes in the gap a. between it and the casing 1. In the last section 9, the air enters the full flow and after cooling leaves the air cooler through the pipe 3. silt. (L 00 from Fri 7 #

Description

The invention relates to refrigeration equipment, namely, air coolers for climate and refrigeration chambers,

The purpose of the invention is to reduce energy consumption by more evenly distributing it over the heat exchange sections of the device,

The drawing shows schematically the cooler, a longitudinal section.

The air cooler includes a casing I with inlet 2 and outlet 3 nozzles and a fan 4 placed in it, and heat exchange sections 5-9, installed with a gap 1 one relative to another and a gap O. relative to the shell I, the gap 1 allows the turbulence of air flow and increase the amount of heat removal from each section of the heat exchanger, and in the gap 3. there are cakes of the heat exchange sections 5-9, participating in the process of air cooling. Valves 10, mounted behind each heat exchanger section 5-9 id, are attached to the casing 1 at a distance S, defined by the ratio

i n-i ::

2 p-g

where 1 is the distance between sections,

m ;. i is the valve serial number according to

air movement; n is the number of sections.

The distance Sj is reduced from an initial value of 1/2 to a final zero value. The flaps 10, due to the airflow rotations, create additional turbulization, prevent the direct bypassing of the heat exchange sections 5-9 by this flow and allow to improve the uniformity of sedimentation in the depth of the air cooler.

In the cooling and frosting mode, the air cooler works as follows.

Through the fan 4, air flows through the inlet 2 to the inlet of the first heat exchange section 5 and then to the subsequent sections 6-9. In the initial period of operation of the air cooler, the air flow passes mainly through the heat exchange sections 5-9 because their hydraulic resistance is less hydraulic resistance of the gap and the distance Si.

five

five

0

five

d j

CQ, f The cooling process1: the air in surface apparatuses occurs at the temperature of the external surface of heat exchange 3–12 ° C below the temperature of the cooled air. In most cases, the temperature of the heat exchange surface is lower than the dew point temperature, therefore, with negative temperatures, the process of cooling the air is characterized by condensation of moisture in the form of heat on the heat exchange surfaces.

At the entrance to the first heat exchange section 5, the difference in moisture content in the air and near the surface is heat exchange is greatest, which determines the intensive frost formation on it. As the annulus and intercostal spaces are clogged with frost of the first heat exchange section 5, the air flow is redistributed due to an increase in its hydraulic resistance. This increases the proportion of the air flow passing through the gap a. between section 5 and skin-. Home 1, with some of the moisture passing to the next sections 6-9, which increases the proportion of the moisture load on them.

As further deposition does not occur in section 6, the redistribution of the air flow passing through it and in the gap D between it and the casing 1 also occurs.

Through the last section of the air cooler, isn, a full flow of air passes, since the distance S for this last section is equal to

S, i (1 - iEJ) "o,

I

those. for any given number of sections T1, the distance S is always equal. zero

to the last section 9, the air is supplied with a full flow and after cooling it leaves the air cooler through pipe 3,

The use of the proposed technical solution allows an increase in the duration of the air cooler operation between periods of thawing of a snow coat on its heat exchange surfaces, which, in turn, reduces energy costs, as compared with the prototype.

31413384-i

Claims (1)

Claims of the invention for each heat exchanger section of the air cooler on An air cooler containing a distance S ;, determined by the cultivator and the fan placed in it and. heat exchange sections installed with a gap one relative to the other i and with respect to the casing, the difference is S g (1 - - t), u and with the fact that, in order to reduce -. ki of energy consumption is more equal, Q where 1 is the distance between sections of} and the measured heat distribution over heat; 1 is the order number of the damper along the exchange sections, it is equipped with a barrier to air movement; we attached to the casing and usn - the number of sections.