WO2020204759A2

WO2020204759A2 - Membrane heat exchanger

Info

Publication number: WO2020204759A2
Application number: PCT/RU2020/000169
Authority: WO
Inventors: Александр Николаевич ЗОЛЬНИКОВ
Original assignee: Александр Николаевич ЗОЛЬНИКОВ
Priority date: 2019-04-03
Filing date: 2020-04-03
Publication date: 2020-10-08
Also published as: RU2711860C1; WO2020204759A3

Abstract

The invention is intended for use in combined supply and exhaust ventilation systems in residential and industrial buildings. A membrane heat exchanger comprises a heat-exchanging membrane made from a thin-walled sheet in the shape of a zigzag, which forms ribs that are perpendicular to the long side of the sheet. The heat-exchanging membrane is installed into a shell that fastens the membrane such that the end faces of the membrane are hermetically sealed, and slits for the admittance of air are configured in opposite sides of the shell. The invention increases the efficiency of heat transfer.

Description

Membrane heat exchanger

The invention is intended for use in supply and exhaust ventilation systems of residential and industrial buildings, premises, livestock complexes and other isolated places where people and animals are located in order to save costs for heating and cooling premises.

The existing known functionally similar devices are mainly represented by plate heat exchangers, which use the same principles of transferring thermal energy.

Plate heat exchangers are made of separate plates located in parallel planes and connected to an assembly using locks or sealant. This creates a multitude of intermittent cavities, half of which are connected to the incoming stream and the other half to the outgoing one. The direction of the air flow in the plate heat exchangers is 90 °.

A plate heat exchanger is known, which contains a package of heat exchange plates with stiffening ribs playing the role of spacer (separating adjacent plates) inserts, the internal cavities of which are filled with sealant, while the stiffening ribs of adjacent plates are located perpendicular to each other, which ensures the rigidity of the assembly and the direction of flows under 90 ° angle [RU2254532 Cl, MnK7F28D 9/00, publ. 2005],

The technical problem, the solution of which is provided by using the invention, is to create a heat exchanger, the parameters and characteristics of which meet the specified requirements.

EFFECT: increased efficiency of heat transfer is achieved due to a large area of contact of membrane surfaces with air flows with a small volume of the heat exchanger.

The specified technical result is achieved by the fact that the membrane heat exchanger contains a cartridge with a heat exchange membrane and a cage fixing it, while the heat exchange membrane has the shape of a thin-walled sheet folded like an accordion with the formation of ribs perpendicular to the long side of the sheet, the ends of the membrane are sealed in such a way that two separated membrane cavities are formed , and slots for air passage are made on opposite sides of the cage. The novelty of the device lies in the method of manufacturing the heat exchange membrane, its shape, the design of the heat exchanger cartridge, as well as in the arrangement of the membrane heat exchanger elements.

Unlike plate heat exchangers, the membrane is made of a single rectangular sheet of material by alternating opposite bends of the sheet at an angle of 180 °. As a result, the sheet takes on a zigzag shape and serves as the main part of the heat exchange cartridge. The distance between adjacent folds forms the depth, the height of the folds - the height, and the thickness of the ribs and their number - the width of the cartridge. The ends of the membrane are sealed with two end plates, after which two cavities separated by the membrane are formed, into which air flows (supply and exhaust) are supplied from opposite directions, which contributes to more efficient heat transfer than when the flows are directed at an angle of 90 °.

Thus, the proposed design of a membrane heat exchanger is characterized by an increased efficiency due to the direction of flows at an angle of 180 °, as well as ease of assembly, a decrease in the number of technological operations during production and, accordingly, a lower cost and greater availability for consumers.

Figure 1 shows a diagram of the manufacture of a heat exchange membrane.

FIG. 2 shows the assembly diagram of the heat exchanger cartridge.

Fig. 3 schematically shows the device of a membrane heat exchanger, the heat exchange membrane is conventionally shown by a line, arrows show the directions of air flows.

The device consists of a replaceable cartridge and housing.

The membrane heat exchanger includes a cartridge with a heat exchange membrane 1 and a cage 2 that fixes it. The heat exchange membrane 1 has the form of a thin-walled sheet 3 folded like an accordion, for example, metal or other material of similar strength and thermal conductivity. The heat exchange membrane 1 is made as follows: a thin-walled sheet 1 is folded in one direction or the other at an angle of 180 °, forming ribs 4 perpendicular to the long side of the sheet (Fig. 1). After the end of the folding process, the ends of the assembly 5, formed by the edges of the folded sheet 3 of the membrane 1, are sealed. Membrane 1 is made of an air-moisture-proof material with good thermal conductivity, for example, from a rectangular sheet of aluminum alloy with a thickness of 0.2-0.5 mm. The distance between the folds forming the ribs 4, the thickness of the ribs, the width, length and thickness of the sheet 3, as well as the material itself for the manufacture of membrane 1 is selected depending on the requirements for productivity, device efficiency and cost.

The manufactured membrane 1 is placed in the holder 2 that fixes it. Figure 2 shows a diagram of the assembly of the heat exchanger cartridge, where 6 are the slots for air supply and discharge, 7 are the side elements of the holder, 8 are the end elements of the holder, 9 are the places for installing the elements of the holder. On two opposite sides of the cage 2, slots 6 are provided for air passage. The width of the slot 6 is calculated for the required throughput. The ends of the assembly 5 of the membrane 1 are sealed with two end plates 7, after which two cavities separated by the membrane are formed.

An exemplary arrangement of heat exchanger elements is shown in FIG. 3, where the heat exchange membrane 3 (conventionally shown by a line) is fixed in the holder 2 installed in the housing 10. Air flows are conventionally shown by arrows. Condensate drain 12 is carried out, for example, through a siphon, 13 is a partition that separates the flows. The body 10 of the device serves to fix the cartridges in the desired position, to place the fans 1 1, equipment and communications of the power supply and control systems, the direction of the air flows, the removal of 12 condensate formed in the cartridge, the connection of the supply and exhaust ventilation ducts.

If necessary, the housing can accommodate several cartridges operating in series and / or in parallel.

The principle of operation of a membrane heat exchanger. Two oppositely directed air flows with different temperatures are forced into the device. Thermal energy is transferred from one stream to another through the heat exchange membrane 3, which has good thermal conductivity and a significant area. The performance or efficiency of a device depends on the following parameters. The efficiency is directly proportional to the area of the membrane in contact with the air flow; time of contact of air with the membrane; thermal conductivity of the membrane; temperature difference between streams; air humidity; air pressure. The efficiency is inversely proportional to the speed of air movement in the device; membrane thickness.

Savings are achieved due to the transfer of thermal energy between the incoming (supply) and outgoing (exhaust) air streams opposite to each other. The transfer of thermal energy occurs through a heat exchange membrane that separates the flows. The efficiency of heat transfer is achieved due to the large area of contact of the membrane surfaces with air flows with a small volume of the heat exchanger. To achieve a significant ratio of the membrane surface area to the volume occupied by the device (100m ² or more in 1m ³ ), the membrane is given a zigzag shape (the shape of a folded accordion).

Claims

Claim

1. Membrane heat exchanger, characterized by the fact that it contains a heat exchange membrane and a cage fixing it, the heat exchange membrane is made of a thin-walled sheet and has a zigzag shape with the formation of ribs perpendicular to the long side of the sheet, while the heat exchange membrane is installed in the cage fixing it in such a way that the ends the membranes are sealed in such a way that two separated membrane cavities are formed, and slots for air passage are made on opposite sides of the cage.

2. Membrane heat exchanger according to claim 1, characterized in that said membrane is made of a rectangular sheet of aluminum alloy with a thickness of 0.2-0.5 mm.

3. Membrane heat exchanger according to claim 1, characterized in that the surface area of the membrane is 100 m ² .