JP2023505282A - Plates for heat exchangers and plate heat exchangers with integrated dryer - Google Patents

Abstract

A heat exchanger is provided that is smaller in size and economical to manufacture. The present invention relates to a heat exchanger (1) comprising a dryer (10) and a water-cooled condenser (12), said condenser (12) comprising a number of plates (8) and two end plates (25). ), wherein said dryer (10) is integrated with said condenser (12) and said plate (8) has openings (9) which are connected to a plurality of plates When (8) is juxtaposed, the opening (9) in said plate (8) is designed to form a cavity and/or one or more of the end plates (25) are It has a cavity, said cavity being suitable for accommodating a dryer (10) and/or a desiccant (11). [Selection drawing] Fig. 6g

Description

The present invention relates to plates for heat exchangers and plate heat exchangers with integrated dryers, more particularly condensers having multiple plates and optionally two end plates with integrated receivers. Plates for heat exchangers and plate heat exchangers with integral dryers including (end plate).

A plate heat exchanger is a special design of a heat exchanger consisting of plates arranged in successive gaps for the flow of a medium which is first heated and then dissipated. A plate pack is sealed outwardly and between media.
Currently, water-cooled condensers are manufactured with a plate-plate or plate-lamella structure. Depending on the design of the water-cooled condenser, the desiccant is placed and stored in a separate external refrigerant collector-drier vessel.
In known condensers such external collector-drier vessels are located outside the condenser as storage/drier bins. A plate heat exchanger for an air-conditioning circuit is known from US Pat. Said plate heat exchanger comprises a cylindrical collector-dryer and is (externally) arranged on one of the two end plates as in FIG.
A dryer located externally on one of the two end plates has the disadvantage of increasing the size of the water cooled condenser assembly. Also, if a collection dryer bottle is used as the dryer, a connecting tube or connecting block is required. Alternatively, a screw-on collector drier bottle may require additional assembly steps.

French patent invention No. 3001795

It is an object of the present invention to provide a heat exchanger that is smaller in size and more economical to manufacture.

The object of the invention is solved by a plate heat exchanger of the form mentioned at the outset, in which the collector-dryer is integrated into the condenser and the plates have openings, in which case , the openings are designed such that when multiple plates are juxtaposed, the openings in said plates form a cavity and/or one of the end plates has a cavity, when said cavity is suitable for containing dryers and/or desiccants. Such embodiments in which the collector-dryer or collector-dryer bottle is located inside the condenser have relatively small dimensions for the condenser, which is particularly important when the heat exchanger is installed in a motor vehicle. Advantageous.
Also, embodiments in which the collector-dryer is located inside the condenser simplify the manufacture of the heat exchanger, thus reducing the cost of the heat dryer.
Another advantage of such embodiments is their smaller size compared to configurations in which the collection dryer bottle is mounted externally on the condenser. In addition, additional parts such as connecting pipes or connecting blocks that can connect the collection dryer bottle and the condenser can be omitted.

The inner part of the condenser is preferably formed by brazing, such as vacuum brazing, in a plate-plate or plate-(cooling-) fin configuration, in which case the condenser comprises refrigerant-carrying layers (refrigerant channels ( refrigerant channel) and a water transport layer (water channel).
The dryer preferably has one or more dryer openings, wherein said one or more dryer openings are connected to the refrigerant transport layer or to one or more refrigerant channels such that the refrigerant flows into the dryer. It is formed so that it can flow into This causes the coolant to flow through a desiccant disposed within the cavity or to physically contact said desiccant to couple the liquid. In this case, the desiccant does not necessarily have to flow through, but reaches the openings by means of diffusion. The desiccant absorbs moisture, but in this case the water does not flow through the dryer through a medium that absorbs or releases heat. For this purpose, the cavity formed by the plates is connected through one or more dryer openings with a condenser space filled with refrigerant.

One or more dryer openings are preferably located in one or more refrigerant-carrying layers of the condenser or connected to one or more refrigerant channels.
The dryer can preferably be closed with a filter closure (reversible) comprising a filter with a sealing ring. Such a design allows for the insertion or replacement of desiccant located in the cavity/dryer.
The opening of the plate is preferably centrally located on the plate surface formed by the plate. However, embodiments of plates in which the aperture is not centrally located in the plate are also conceivable.
In another preferred embodiment of the invention, one or more of the end plates has a cavity, said cavity being connected with the refrigerant circuit by means of a coupling block. Such an embodiment has a narrow structural shape that allows quick changeover of dryers by changing the endplates.

Said coupling block is preferably connected with the end plate through a flange, in which case a sealing ring is arranged between said flange and end plate in a suitable manner. In this case, sealing concepts known in the automotive industry, such as simple double O-rings, metal seal fittings, are used.
The problem of the invention is also solved by a plate for a plate heat exchanger having openings, wherein said openings are designed such that when a large number of plates are juxtaposed, the openings in said plates form cavities. there is
The object of the invention is also solved by the use of the plates according to the invention for use in condensers of plate heat exchangers.

Additional details, features and advantages of embodiments of the present invention appear from the following description of embodiments made with reference to the accompanying drawings. In the Drawing Department:
1 is a perspective view of a plate heat exchanger for an air conditioning circuit with an external collector dryer as known in the prior art; FIG. Fig. 2 is a plan view of a plate according to the invention with circular openings; FIG. 2 is a plan view of a plate according to the invention with oval openings; Fig. 3 is a perspective view of a plate (8) with one aperture (9) and four apertures (13); A cut-out of a plate (8) with openings (9) is illustrated. Fig. 3 is a side view of a plurality of laminated plates (8) that together form the inner part (30) of the condenser (12); Fig. 2 is a cross-sectional view of a cavity/dryer located inside the condenser; FIG. 2 is a cross-sectional view of a water-cooled condenser (12) comprising an integral dryer (10) with a condensation section (18). FIG. 2 is a cross-sectional view of a water-cooled condenser (12) with a subcooling section (20). Fig. 3 is a cross-sectional view of a water-cooled condenser (12) with an inlet section (19); Fig. 3 is a cross-sectional view of a water-cooled condenser (12) having an inlet section (19) and a condensation section (18); Fig. 3 is a cross-sectional view of a water-cooled condenser (12) having an inlet section (19) and a subcooling section (20); FIG. 2 is a cross-sectional view of a water-cooled condenser (12) having a subcooling section (20) and a condensing section (18). FIG. 2 is a cross-sectional view of a water-cooled condenser (12) having an inner part (core) (30) comprising an inlet section (19), a subcooling section (20) and a condensing section (18). FIG. 2 is a cross-sectional view of a water-cooled condenser (12) having an inner part (core) (30) comprising an inlet section (19), a subcooling section (20) and a condensing section (18). 1 is a schematic diagram of a water-cooled condenser with integrated dryer; FIG. 1 is a schematic diagram of a water-cooled condenser with integrated dryer; FIG. 1 is a schematic diagram of a water-cooled condenser with integrated dryer; FIG. Fig. 4 is a schematic cross-sectional view of a second embodiment of the invention;

FIG. 1 illustrates a plate heat exchanger (1) as known in the prior art, with an externally arranged collector-drier bottle as receiver, ie a refrigerant collector bottle/dryer vessel (2).
A plate heat exchanger (1) comprises a condenser (3) formed by a number of plates (4) and two end plates (5). The corners of the plate (5) are arranged with openings (7) for the inflow and outflow of water and coolant.
The collection dryer bottle (2) is connected with the refrigerant side condenser (3) through a connecting block (6) or a connecting tube.
Figures 2 and 3 show a plate (8) with openings (9), where said openings (9) can be used by a dryer (9) when multiple plates (8) are juxtaposed or stacked. 10) and the desiccant in the desiccant bag (11) can be filled, thus forming a cavity used as collector-dryer (10) for the condenser (12). .

In the embodiment of the plate (8) illustrated in FIG. 2 the apertures (9) are circular and in the embodiment illustrated in FIG. 3 they are elliptical. However, the openings (9) can also have other shapes, for example angular shapes, and can be arranged at other positions on the plate (8).
The plate (8) has additional openings (13). Refrigerant or water flows through such openings (13) in the condenser (12) formed by the plates (8).
Figure 4a illustrates a three-dimensional drawing of a plate (8) with one aperture (9) and four apertures (13).
Figure 4b illustrates the cut-out of the plate (8) with the opening (9), r also illustrated in 4a.
Figure 4c illustrates a plurality of laminated plates (8) which together form the inner part (30) of the condenser (12).

A cavity is formed in the center of the condenser (12) at some point of the opening (9) by the stacking plates (8) and filled with desiccant (11) or collector-drier (10). is placed inside it. A brazed surface (14) of the dryer (10) forms a connection between the container and the plate (8).
The dryer (10) has one or more dryer openings (15) illustrated in FIG.
Figures 5 and 6 illustrate an embodiment and are described together below.
FIG. 5 illustrates in detail a schematic diagram for the inter-circuit connection of the dryer (10) and the water-cooled condenser (12). Suitably the dryer (10) is formed as an aluminum cartridge/bottle and is connected by brazing with the plate (8) of the condenser (12). The cartridge or bottle suitably has a plug with a sealing O-ring and a sealing face for the filter and is made of an extruded aluminum profile with internal threads. Such embodiments with plugs and sealing-O-rings are easy to maintain when changing desiccants. Within the cavities filled with desiccant there is pressure that can connect such cavities with plate heat exchangers.

The desiccant (11) is suitably inserted from the bag into the dryer (10) and the dryer (10) is subsequently closed by the filter closure (24) according to Figures 6g and 6h.
The dryer (10) is configured as a vessel that passes through the inner part (30) of the condenser (12) in the middle of the plate (8).
The water-cooled condenser (12) with the dryer bottle integrated in the inner part (core) (30) is also manufactured with "One-Shot" brazing, so the external dryer vessel or external dryer No additional assembly steps are required to mount the bottle.
Coolant channels (16) and waterways (17) extend between the plates (8).
The dryer (10) allows refrigerant to flow through or connect to the vessel of the dryer (10) through one or more dryer openings (15) which simultaneously form open channels (23). Refrigerant flows through a dryer (10) and a desiccant (11) (illustrated at 21). The dryer vessel (10) comprises refrigerant channels (16) in the condensing section (18) and/or the inlet section (19) and/or the subcooling section (20) through one or more dryer openings (15). can be linked to However, in the case of the waterway (17), the dryer (10) is closed (closed channel (22)).

The inlet section (19) is designed as the inner (30) area of the condenser (12), which means that several successive plates (8) form spaces for the refrigerant. .
By connecting the desiccant (11) to the refrigerant circuit, the desiccant (11) can absorb moisture from the system.
In a water cooled condenser (12) it is important that the collector-dryer (10) is fully integrated with the heat transfer plates (8) of the plate heat exchanger (1). Depending on the embodiment, the integral dryer (10) may include a subcooling section (20) (subcooling zone), an integral collection vessel or inlet section (19), a final condenser plate, ie end plate (25), or type and It can be arranged in combinations of additional embodiments possible by the flow profile.
The heat exchanger design with inlet section can be used for all water condenser configurations with different section combinations as illustrated in Figures 6a-6h.

Figures 6a-6h show a water-cooled condenser ( 12).
Figure 6a is a cross-sectional view of a water-cooled condenser (12) comprising an integral dryer (10) with a condensation section (18).
Figure 6b is a cross-sectional view of a water cooled condenser (12) with a subcooling section (20).
Figure 6c is a cross-sectional view of a water cooled condenser (12) with an inlet section (19).
Figure 6d is a cross-sectional view of a water cooled condenser (12) having an inlet section (19) and a condensation section (18).
Figure 6e is a cross-sectional view of a water cooled condenser (12) with an inlet section (19) and a subcooling section (20).
Figure 6f is a cross-sectional view of a water cooled condenser (12) having a subcooling section (20) and a condensing section (18).

Figures 6g and 6h are cross-sectional views of a water-cooled condenser (12) having an inner part (core) (30) comprising an inlet section (19), a subcooling section (20) and a condensing section (18). The integrated dryer (10) with desiccant (11) is closed with filter closures (24, 25) comprising a filter (31) and plugs with seals (block with seals (31)). shown).
The embodiment of the water cooled condenser (12) illustrated in Figure 6h additionally has internal tubes (32) that allow the refrigerant to bypass the subcooling section (18).
In Figures 6g and 6h, for example, the connection with the dryer (10) (vessel) is illustrated by points, which indicate, for example, how the refrigerant flows through the dryer (10), i.e. the diagram Refrigerant flows through the dryer while the refrigerant flowing through refrigerant channels (16) passes through the vessel through one or more dryer openings (15) according to the fifth embodiment. The channel (17) is not connected to the dryer (10).
The arrows shown in Figures 6a-6h illustrate the direction of flow of the refrigerant and water within the condenser (12).

The technique of having an integral inlet as inlet section (19) can be used for all other plate heat exchangers (1) with an integral collector-dryer (10) illustrated in Figures 7a-7c. The embodiment illustrated in Figures 7a-7c has two water inlet openings (40, 44) and two water outlet openings (41, 45) and two coolant inlet openings (42, 46) and two coolant outlet openings (42, 46). 43, 47).
Figure 7a illustrates a plate heat exchanger (1) combining a water cooled condenser (12) and an integral heat exchanger (33).
Figure 7b illustrates a plate heat exchanger (1) combining a water cooled condenser (12), an integral heat exchanger (33) and an evaporator (34).
Figure 7c shows a plate heat exchanger (1) connecting a water cooled condenser (12), an integral heat exchanger (33), an evaporator (34) and respective additional refrigerant and coolant heat exchangers (35). Illustrate.
Figure 8 illustrates a cross-sectional view of a second embodiment of the present invention having an inner part (30) where the collector-dryer is integrated into the end plate (25) of the water cooled condenser (12).

The end plate (25) has a cavity in its interior which is used to contain the desiccant, so the end plate (25) is flat and therefore fits the condenser (12) in a space-saving manner. Becomes an integrated desiccant container.
In this case the end plates (25) do not have the full length of the remaining plates (8) and are shorter than the plates (8) forming the condenser (12).
The end plate (25) is connected to the coupling block (37) through a flange (36), in which case the end plate (25) and the coupling block (37) have the same dimensions as the plate (8) by Linked in a space-saving manner.

The coupling block (37) has an additional side outlet through which the coolant passes. Through the coupling block (37) the desiccant in the end plate (25) contacts one or more coolant channels.
For fixing, the flange (36) and the coupling block (37) are connected to each other through threaded bolts and nuts (38) according to the illustrated embodiment. A seal (39) is located between the flange (36) and the coupling block (37) for sealing.
Apertures of this type can also be used as sections for heating/cooling electronic components inserted into the cavity. This technology can also be used with water/water or water/oil or water/air or multi-fluid heat exchangers (two or more).

The present invention relates to a plate heat exchanger comprising a dryer and a water-cooled condenser, wherein said condenser comprises a number of plates and optionally an integrated receiver. It contains two end plates with .
The present invention also relates to a plate for a plate heat exchanger having openings and its use.

Claims (11)

As a heat exchanger (1) comprising a dryer (10) and a water-cooled condenser (12), said condenser (12) comprising a number of plates (8) and two end plates (25),
said dryer (10) is integrated with said condenser (12),
Said plate (8) has openings (9) which are arranged such that openings (9) in said plates (8) form cavities when a plurality of plates (8) are juxtaposed. is designed to
and/or one or more of the endplates (25) has a cavity,
Heat exchanger (1) with integrated dryer, characterized in that said cavity is suitable for containing a dryer (10) and/or a desiccant (11). The inner part (30) of said condenser (12) is formed by brazing in a plate-plate or plate-(cool-) fin configuration, said condenser Heat exchanger (1) with integrated dryer according to claim 1, characterized in that (12) comprises a refrigerant-carrying layer (16) and a water-carrying layer (17). said dryer (10) having one or more dryer openings (15), wherein said one or more dryer openings (15) are connected with said refrigerant carrying layer (16); A heat exchanger (1) with an integrated dryer according to claim 1 or claim 2, characterized in that it is formed as a. 4. A unitary dryer according to claim 3, characterized in that said one or more dryer openings (15) are located in one or more refrigerant-carrying layers (16) of said condenser (12). heat exchanger (1). Heat exchanger (1) with integrated dryer according to any one of the preceding claims, characterized in that the dryer (10) can be closed by a filter closure (24). 6. One according to any one of claims 1 to 5, characterized in that the opening (9) in the plate (8) is arranged in the center of the surface formed by the plate (8). A heat exchanger (1) with a body dryer. Integral according to claim 1, characterized in that if one or more of the end plates (25) has a cavity, said cavity is connected with the refrigerant circuit by means of a coupling block (37). A heat exchanger (1) with a dryer. Heat exchanger (1) with integrated dryer according to claim 7, characterized in that said coupling block (37) is connected with said end plate (25) through a flange (36). Heat exchanger with integral dryer according to any one of claims 1 to 8, characterized in that electronic components for heating or cooling are arranged in the opening (9) (1). As a plate (8) for a plate heat exchanger (1) with openings (9),
A plate for a plate heat exchanger, characterized in that the openings (9) are designed such that the openings (9) in the plates (8) form a cavity when the plates (8) are juxtaposed. (8). Use of a plate heat exchanger plate (8) according to paragraph 10 for use in a heat exchanger (1).

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