SU1536091A1 - Method of removing frost from air-cooler surface - Google Patents

Abstract

The invention relates to refrigeration engineering, in particular, to methods for removing air from the surface of air coolers used in refrigeration and refrigeration units. The purpose of the invention is to intensify the removal process. To do this, the removal is not carried out with chilled air flows supplied along the longitudinal axis of the air cooler from the rear plate 6 towards the fans 3, and perpendicular to the main one with at least one additional cold air flow from the bottom plate 5 upwards or from the top plate 4 down to the evaporative pipes 1 and ribs 2. In order to ensure that the movement of cold air is uniform and ensure uniform removal throughout the entire surface, the fans 3 are created to underpressure during the removal process to remain underpressure and. 2 ill., 1 tab.

Description

The invention relates to refrigeration engineering, in particular, to methods for removing air from the surface of air coolers used in refrigeration and refrigeration units.

The purpose of the invention is to intensify the removal process.

FIG. 1 shows an air cooler for implementing the proposed method in the working position while cooling the product; in fig. 2 - the same, in the delete mode.

The air cooler contains evaporator tubes 1, equipped with fins 2, and two fans 3.

Hollow plates 4-6 are installed in the upper, lower and rear parts of the air cooler, equipped with a number of nozzles 7. The plates 4-6 are divided by partitions 8 into sections serving as collectors. The plates 5 and 6, located in the lower and rear parts of the air cooler, are installed in the guides 9 and 10 with the possibility of reciprocating motion.

Top plate 4 is fixed. Flexible hoses 12 are supplied to each section of the plates from the distributor 11 for supplying cooled compressed air.

The method is carried out as follows.

When the air cooler is operating in cooling mode, the air is supplied by fans 3 to the surfaces of pipes 1 and fins 2, cooled and directed to the refrigerating chamber. At this time, plates 5 and 6 are extended and do not prevent the passage of cooled air into the refrigerating chamber. In the removal mode from the surfaces of the pipes 1 and the fins 2 of the plates 5 and 6, along the guides 9 and 10 are installed so that: and the surfaces fit snugly I, the ends of the evaporator pipes 1. To the sections of the plates 4-6 through 12

compressed air is supplied that has been pre-cooled to a temperature corresponding to the temperature of the air in the refrigerating chamber. The cooled compressed air enters the cavities of the sections of the plates 4-6, where an overpressure of 0.96 -1.2 MPa is created, and further to the nozzles 7. At the same time, a flow of cooled air is supplied

along the longitudinal axis of the air cooler from the plate 6 towards the fans 3 and supplying at least one additional stream of cold air, perpendicular to the main air, for example, from the bottom plate 5 upwards or from the top plate 4 downwards, or simultaneously feeding two perpendicular to the main flows from the plates 4 and 5. To allow the movement of cold air,

directed to the evaporator tubes 1 and the fins 2, was uniform up to the intersection of the streams, for even removal throughout the entire volume of the air cooler and for its removal

the course of the air cooler create

, five

a vacuum of 0.85 - 0.95-10 Pa by fans 3. The cooled air is alternately supplied to the section of the plates 4-6 in order to create more intensive air movement. The number of sections simultaneously turned on depends on the cross-sectional area of the openings of the nozzles 7, the parameters and the amount of incoming air.

45

0

five

When removing a layer thicker than 5 mm, the power consumption for removing it increases by 15–20%. In this case, depending on the operating conditions, additional defrosting of the air is necessary. laditelle

The table shows the values describing the degree of distance from the ratio of inlet pressure, flows to the air cooler and vacuum at the outlet of the non-condenser: 5 at a layer of 5 mm.

536091

. at the inlet of 0.96 - 1.2 MPa and a vacuum at the output of 0.85 - 0.95-10 Pa.

The addition of an additional stream of cooled air makes it easier to break up on the surface of the air cooler due to the initial impact on thinner layers, which, when destroyed, leads to a significant decrease in adhesion to the surfaces of the air cooler of the remaining layer.

Discharge at the exit of the air - cooler creates an additional 15 internal load on the layer and does not contribute to its destruction. All this allows to intensify the process of removal of air from the surface of the air cooler.

The greatest degree of removal is not achieved under overpressure.

Claims (1)

Invention Formula The removal method is not from the air cooler surface by supplying a stream of cooled air along the longitudinal axis of the air cooler, characterized in that, in order to intensify the removal process, at least one additional stream of cooled air is fed to the main one, and at the entrance of both streams to the air cooler create an overpressure in the range of 0.96 - 1.2 MPa, and at the exit from the air cooler, a vacuum of 0.85 - 0.95-10s Pa is created. v ;  „ vnvvniY 2 // and