SU1079998A1 - Regenerative heat exchanger - Google Patents

Abstract

1. A REGENERATIVE HEAT EXCHANGER, comprising a housing divided by a partition into channels for a heated and heating medium and an impeller rotating in the channels with shaped blades formed by heat pipes, and with , in order to intensify heat exchange, guide vanes are installed along the outer and / or inner perimeter of the impeller 2. Heat exchanger according to claim 1, characterized in that the guide vanes are placed between the blades 3. The heat exchanger according to claim 1, о t -. characterized in that the guide vanes are placed along the axial lines of the blades, and the heat pipes of the latter are arranged in a staggered order. 4. Heat exchanger according to claims. 1-3, which is similar, with E; the purpose of increasing the efficiency, the action, the guide vanes located along the inner peri-meter of the impeller are made with a chord length of 1.0-3.0 of the diameter of the heat pipe. (L / 3 / * h1CO < o < p: 00

Description

The invention relates to devices used in heating, ventilation and air conditioning systems.

A regenerative heat exchanger for ventilation and air conditioning is known, comprising a housing with dividing walls for a heated and heating environment, an impeller with a partition rotating in the housing, and heat pipes mounted on annular ribs coaxial to the impeller 13.

However, at low temperatures, the outside air needs to be preheated by a carolifer prior to entering the heat exchanger to prevent the heat pipes from freezing.

A regenerative heat exchanger is known, comprising a housing divided by a partition into channels for a heated and heated medium and an impeller rotating in the channels with profiled blades formed by heat pipes 2.

A disadvantage of the known heat exchanger is the low intensity of heat exchange, the low efficiency.

The purpose of the invention is to intensify heat exchange, increase the efficiency,

The goal is achieved in that in a regenerative heat exchanger comprising a housing divided by a partition into channels for a heated and heating medium and an impeller rotating in the channels with profiled blades formed by heat pipes along the outer and / or inner perimeter of the impeller .

The guide vanes are located between the blades.

The guide vanes can be placed along the axial line of the blades, and the heat pipes of the latter are arranged in a checkerboard pattern, and the guide vanes located along the inner perimeter of the impeller are made with a chord length of 1.0-3.0 times the diameter pipes.

FIG. 1. shows the proposed regenerative heat exchanger, top viewJ in FIG. 2 is a regenerative heat exchanger with guide vanes between the blades, front view; in fig. 3 - regenerative heat exchanger with guide vanes placed along the axial lines of the blades, front view; in FIG. 4, node I in FIG. 3

The regenerative heat exchanger includes a housing 1 divided by partitions 2 and 3 into channels 4 and 5, respectively, for the heated and heating medium and the impeller B. The impeller b includes disks 7 and 8, profiled blades 9 from heat pipes 10 and a partition 11. There are guide vanes 12 installed between the profile blades 9 along the inner and outer perimeters of the impeller 12. A seals 13 are mounted between the partitions 2 and 3.

The drive of the impeller 6 is implemented. is from engine 14 via belt drive 15.

Regenerative heat exchanger works as follows.

During rotation of the impeller b by the electric motor 14 through the belt drive 15, the heated and heating medium is captured by the profile blades 9 and the guide vanes 12 installed along the outer perimeter of the impeller b and moves along the channels 4 and 5 according to the principle of the fan. The separate transport of the streams is provided by the separation walls 2 and 3, the partition walls 11 and the seals 13. The guide vanes 12 installed along the inner perimeter of the impeller 6 direct the air flow in the diametrical direction and provide a shock-free entrance and exit from the air flow vanes. Due to the temperature difference between the heating and heated media, evaporation of the coolant occurs in the area of heat pipes 10 located in channel 5 (evaporation zone). When the heat carrier evaporates, heat is removed from the heating medium, formed by the vapor pairs, and transferred to the second part of the heat pipes 10, located in channel 4 (condensation zone), where it is washed by a ng1 heated medium having a lower temperature. As a result of the cooling down, the process of condensation of the coolant occurs, in which the heat released is transferred to the heated medium. The condensed coolant under the action of 0 centrifugal forces is transferred to the evaporation zone. The condensate formed in channel 5, as a result of cooling of the coolant below the dew point, under the action of centrifugal 5 forces is thrown to the housing 1 and does not freeze to the surface of heat pipes,

The economic effect obtained by 0 using the pre- regenerative heat exchanger, arises due to the intensification of heat exchange.

/ g Yu. K / / / X /

ipus.2

Claims (4)

1. REGENERATIVE HEAT EXCHANGER, comprising a housing divided by a partition into channels for naked, heated and heating media, and an impeller rotating in the channels with profile blades formed by heat pipes, characterized in that, with the aim of intensifying heat exchange, the external and / or the inner perimeter of the impeller mounted guide vanes. 2. Heat exchanger according to π. 1, characterized in that, the guide vanes are placed between the blades. 3. Heat exchanger according to π. 1, characterized by the fact that the guide vanes are placed along the axial lines of the blades, and the heat pipes of the latter are staggered. 4. The heat exchanger according to paragraphs. 1-3, characterized in that, in order to increase the efficiency, the actions of the guide vanes located along the inner perimeter of the impeller are made with a chord length of 1.0-3.0 of the diameter of the heat pipe. t £ fi? .1 * 4 СО with СО Q0>