RU72306U1 - HEAT AND WATER EXCHANGER - Google Patents

Abstract

1. A heat and moisture exchanger, including side plates in which openings for gas inlet and outlet are made, upper and lower covers, heat-insulating gaskets and a package of plates installed between the side plates and heat-insulating gaskets, each of which has recesses in the upper and lower parts, two side holes forming gas collectors during assembly of the plates, a ridge-shaped portion in the central part consisting of ribs, while the side holes and ribs are located symmetrically with respect to the vertical axis of symmetry plates, a slot is made above the ribs, which is connected to one of the side holes, while in the package the ribs of adjacent plates are directed towards each other and a polymer film-membrane is located in a zigzag pattern, separating them between themselves. 2. The heat and moisture exchanger according to claim 1, characterized in that the ribs are equidistant from each other. The heat and moisture exchanger according to claim 1, characterized in that the ribs in the upper and middle parts are connected by jumpers. The heat and moisture exchanger according to claim 1, characterized in that the side plates, heat-insulating gaskets and plates have openings for assembly at the corners. The heat and moisture exchanger according to claim 1, characterized in that the covers are provided with rubber gaskets.

Description

The utility model relates to heat and moisture exchange devices and is intended for heat and moisture exchange between gaseous streams.

A heat and moisture exchanger is known comprising a packet of hygroscopic capillary-porous plates forming channels for air flows, a tray with a liquid sorbent solution into which the plates are partially immersed, a bath with slots in the bottom, into which the upper ends of the plates are inserted, and a solution lifting section with pipes filled capillary-porous material and inserted at its ends into the bath and the tray (see SU, No. 1041815, F24F 3/147, 1983).

Also known is an air heater operating on the principle of heat and moisture exchange, containing an air distribution box, a housing with partitions and a heat exchange package installed in it, made in the form of plates vertically mounted in a pallet of a wettable capillary-porous material coated with a moisture-proof layer on one side and forming dry and wet channels for air flows damped in pairs and alternately from the end sides, a supply pipe with nozzles is installed above the heat exchange package, the oddon is equipped with an overflow and outlet pipe, and soft gaskets are installed between the end plates of the heat transfer package and the partitions (see RU, No. 2075697, F24F 3/147, 1997).

The disadvantages of the known heat and moisture exchangers are a decrease in the thermal conductivity of a capillary-porous material at high temperatures, the need for additional wetting of this material

water to increase its thermal conductivity, which leads to a decrease in the efficiency of the process of heat and moisture exchange.

The technical result that can be obtained from the use of the proposed utility model is to increase the efficiency of the heat and moisture exchange process.

The indicated technical result is achieved in the design of a heat and moisture exchanger, including side plates in which openings for gas inlet and outlet are made, upper and lower covers, heat-insulating gaskets and a plate package installed between the side plates and heat-insulating gaskets, each of which has recesses in the upper and lower parts , two side openings forming gas collectors during the assembly of the plates, a ridge-shaped portion in the central part consisting of ribs, the side openings and ribs being wives symmetrically with respect to the vertical axis of symmetry of the plate, a slot is made above the ribs, which is connected to one of the side holes, while in the packet the ribs of adjacent plates are directed towards each other and between the plates there is a zigzag polymer film-membrane separating them from each other.

In the plate, the ribs can be equidistant from each other, and in the upper and middle parts are connected by jumpers. In addition, side plates, heat-insulating gaskets and plates have holes for assembly at the corners. The upper and lower covers are equipped with rubber gaskets.

The essence of the claimed utility model is illustrated by drawings.

Figure 1 presents a General view of the heat and moisture exchanger, figure 2 shows the plate, figure 3 shows the location in the package of plates and a polymer film-membrane between the plates.

A heat and moisture exchanger is a device used in installations requiring humidified and warmed air relative to the environment for their operation. Heat and moisture exchange process occurs

due to the use of heat and moisture contained in the exhaust air leaving the unit.

The heat and moisture exchanger (see figure 1) contains a package 1 of plates 2, side plates 3 and 4, which are identical and are placed in the heat and moisture exchanger with a rotation of 180 ° relative to the vertical axis. Side plates 3 and 4 ensure uniform pressure of plates 2. There are holes on the side plates: one input and two output. Through the inlet 5 located on the side plate 3, warm and moist air is supplied from the installation, and through the inlet (not shown) of the side plate 4, air is supplied from the environment. Through the outlet 6, atmospheric air moistened and heated in a heat and moisture exchanger is discharged into the installation. The hole 7 is designed to discharge the heat and moisture transmitted air from the installation. The heat and moisture exchanger has an upper 8 and lower (not shown in the drawing) identical covers, which are equipped with rubber gaskets 9, and heat-insulating gaskets 10.

Each plate 2 (see Fig. 2) has recesses 11, 12 in the upper and lower parts, two side holes 13 and 14, a ridge-shaped portion in the central part. The crest-shaped portion consists of ribs 15. Two side holes 13, 14 and ribs 15 are located symmetrically with respect to the vertical axis of symmetry of the plate. Over the ribs 15, a slot 16 is made, which is connected to one of the side holes 13. The ribs in the central and upper parts are connected by jumpers 17.

In the package 1 (see Fig. 1), the ribs 15 of the adjacent plates 2 are directed towards each other. When assembling the plates into the package, the side openings 13 and 14 form gas collectors 18 and 19 in the heat exchanger.

When installing the upper 8 and lower covers with rubber gaskets 9, the upper and lower exhaust manifolds for gases (not shown) are formed in the heat and moisture exchanger in the plates 2 above and below the recesses 11, 12. Thermal insulation pads 10

prevent heat loss in the air collectors on the outer plates of 2 packages.

Side plates 3 and 4, heat-insulating gaskets 10 and plates 2 have holes 21, 22, 23 at the corners for assembly.

In the package 1 (see figure 3) between the plates 2 in a zigzag pattern in the form of a continuous web is a polymer film-membrane 20 that separates the plates between themselves and serves as the interface between the inlet and outlet oppositely directed air flows. Through the polymer film-membrane 20 in the heat and moisture exchanger, heat and moisture are transferred.

In the heat and moisture exchanger, moist and heated air from the unit, coming through the inlet 5 on the side plate 3, enters the collector 18, from which it is distributed (see Fig. 3) to the odd (if counted from left to right) plates 2 and then through the slot 16 moves from top to bottom between the ribs 15. Atmospheric air through the inlet (not shown) of the side plate 4 enters the manifold 19, from which it passes through even plates from below. Air from the unit, transferring heat and moisture to the atmospheric air, enters the formed lower outlet manifold and is discharged through the opening 7. Prepared heated and humidified atmospheric air enters the formed upper outlet manifold and is discharged through the opening 6 to the installation. The exhaust air outlet from the lower exhaust manifold and the prepared atmospheric air from the upper exhaust manifold can be arranged both on the two side plates 3 and 4, and on any one of them, and it is necessary to plug the unused outlet.

The countercurrent of air flows created in the inventive heat and moisture exchanger, separated by means of a membrane film, ensures efficient transfer of the thermal energy and moisture to the input atmospheric air by the exhaust air from the unit. For heat and

moisture exchange in this device does not require additional supply of moisture and heat from other sources, which saves energy spent on preparing the input atmospheric air flow.

Claims (5)

1. A heat and moisture exchanger, including side plates in which openings for gas inlet and outlet are made, upper and lower covers, heat-insulating gaskets and a package of plates installed between the side plates and heat-insulating gaskets, each of which has recesses in the upper and lower parts, two side holes forming gas collectors during assembly of the plates, a ridge-shaped portion in the central part consisting of ribs, while the side holes and ribs are located symmetrically with respect to the vertical axis of symmetry plates, a slot is made above the ribs, which is connected to one of the side holes, while in the package the ribs of adjacent plates are directed towards each other and a polymer film-membrane is located in a zigzag pattern, separating them between each other. 2. The heat and moisture exchanger according to claim 1, characterized in that the ribs are equidistant from each other. 3. The heat and moisture exchanger according to claim 1, characterized in that the ribs in the upper and middle parts are connected by jumpers. 4. The heat and moisture exchanger according to claim 1, characterized in that the side plates, heat-insulating gaskets and plates have openings for assembly at the corners. 5. The heat and moisture exchanger according to claim 1, characterized in that the covers are provided with rubber gaskets.