RU2669450C2 - Heat exchanger with the integrated expansion tank and the boiler that incorporates them - Google Patents

Abstract

FIELD: heat exchange.SUBSTANCE: invention relates to the heat exchanger with the integrated expansion tank, which incorporates the boiler, in particular to the heat exchanger with the integrated expansion tank and the boiler, which incorporates all this, where the heat exchanger with the integrated expansion tank has the hot water supply source and the expansion tank, with integral incorporation of the heat exchanger into one shell. In addition, the present invention relates to the heat exchanger with the integrated expansion tank and with the boiler that incorporates them, which can guarantee reliable operation of the membrane and at the same time prevent the membrane, which is an expansion tank, against deformation when it is used for a long time.EFFECT: heat exchanger with the integrated expansion tank is proposed.6 cl, 10 dwg

Description

FIELD OF THE INVENTION

The invention relates to a heat exchanger with an integrated expansion tank and a boiler including them, in particular, to a heat exchanger with an integrated expansion tank having a hot water supply and an expansion tank, with an integral inclusion in one casing with a heat exchanger, and a boiler including all this .

The present invention also relates to a heat exchanger with an integrated expansion tank, which does not allow the membrane constituting the expansion tank to deform even with prolonged use, and at the same time guarantees reliable operation of the membrane and the boiler, which includes the same.

BACKGROUND

Usually, when the temperature of heating the water that circulates in the boiler pipe rises, the volume of heated water increases, and thus the pressure inside the pipe also increases. Thus, it is necessary to use a closed expansion tank, which is adapted to such pressure.

Therefore, since the boiler must include the closed expansion tank described above, in addition to the heat exchanger, for supplying hot water, the manufacture of such a boiler is complicated, and the price of the unit increases.

Thus, in the published patent No. 2012-0089171 of the Republic of Korea, as shown in FIG. 1, the first casing 110a having a gas chamber therein and the second casing 110b having a water chamber therein are mated so as to face each other such so that the hot water heat exchanger and the expansion tank can be represented as a unit, and the partition 150 is inserted between the first casing 110a and the second casing 110b, thereby separating the casing into a water chamber and a gas chamber.

In addition, an elastic bag 130a is installed inside the first casing 110a filled with gas, a heat exchanger pipe 140a for supplying hot water is collected inside the second casing 110b in which the network water flows, and communication holes 151 through which the network water passes are provided in the partition 150.

Thus, the direct-flow water from the heat exchanger pipe 140a, for supplying hot water, is heated by high-temperature network water, which passes through the second casing 110b so that hot water can be supplied, and, in addition, when the temperature of the network water rises and its volume increases , the network water flows into the second casing 110b through the communication holes 151 of the partition 150, to absorb shock.

However, in the above-described prior art, with the large size of each of the communication holes 151 formed in the partition 150, there is no way to prevent the elastic bag 130a from passing through the communication holes 151 and exit in the opposite direction.

Therefore, as shown in figure 2, the elastic bag 130a expands, the elastic bag 130a enters the communication holes 151 of the partition 150, extruded outward in the direction of the opposite side, thus, the elastic bag 130a is deformed if it is in this state for a long time.

In addition, when the communication openings 151 of the partition 150 are clogged as described above, the network water supplied to the water chamber of the second casing 110b pushes the expandable elastic bag 130a and there is no discharge into the gas chamber of the first casing 110a, so the function of the expansion tank is lost.

SUMMARY OF THE INVENTION

Technical problem

The present invention is directed to a heat exchanger with an integrated expansion tank, with the supply of hot water, while the expansion tank is integrated as a whole into one casing of the heat exchanger, and the boiler includes the same.

The present invention is directed to a heat exchanger with an integrated expansion tank, which does not allow the membrane constituting the expansion tank to deform even with prolonged use, and at the same time guarantees reliable operation of the membrane and the boiler, which includes the same.

Technical solution

One aspect of the present invention provides a heat exchanger with an integrated expansion tank, including: a casing of a water chamber comprising a water chamber within which the network water flows, and includes an inlet pipe of network water through which an influx of network water is provided, an outlet pipe of network water through which the discharge of network water is provided, a straight-through inlet pipe through which the flow of straight-through water is provided, and a hot water outlet pipe through which is provided discharge of hot water; the casing of the gas chamber is assembled so as to face the casing of the water chamber to form one casing of the heat exchanger, with the gas chamber formed inside it; a partition inside the heat exchanger casing at the demarcation site between the water chamber and the gas chamber, with a specific region of one side surface, in which there are many openings of the flow of network water, formed in such a way that the network water is dispersed, and its inflow is ensured; the hot water heat exchange pipe is assembled between one side surface of the partition and the water chamber, with an inlet pipe at the end of one of its sides inserted into the inlet pipe of the direct-flow water of the casing of the water chamber, and an outlet pipe at the end of its other side inserted into the hot water outlet of the casing of the water chamber cameras and a membrane collected between the gas chamber and the other side surface of the membrane, expanding due to the expansion gas entering the gas chamber, or in a compressed state due to the supply of network water to the gas chamber through the openings of the network water stream.

The first support protrusion may protrude from the lower surface of the septum in which the membrane is located along the boundary line of a particular area.

The second supporting protrusion may protrude between the openings of the flow of network water of the lower surface of the partition.

Many openings for the flow of network water can be formed in a particular area, circumferentially, at equal intervals, and the dividing line of such a specific area can be in the form of a circle.

At least one or more peeling protrusions may protrude from the lower surface of the septum where the membrane is located.

You can create a bend so that the end of the partition bends outward, and you can create a bend so that the end of the casing of the gas chamber bends inward, and the end of the membrane bends outward, and the membrane can be between the bend of the partition and the bend of the casing of the gas chamber.

Another aspect of the present invention provides a boiler including the above-described heat exchanger with an integrated expansion tank.

Beneficial effects

As described previously, in accordance with the present invention, there is a partition between the casing of the water chamber and the casing of the gas chamber, and a hot water heat exchanger pipe is installed in the water chamber, and the membrane is installed in the gas chamber. Thus, the hot water source and the expansion tank are integrated in one casing with the heat exchanger, thus the cost of manufacturing a boiler can be reduced, and the manufacture of a boiler can be simplified.

In addition, in accordance with the present invention, a plurality of openings for the flow of network water, each has a small size instead of a larger size, are made in the partition, and there are support projections that protrude around this many openings for the flow of network water. Thus, the membrane made of elastic material, even with long-term use, will not be able to deform when placed in the holes of the flow of network water and being extruded in the direction of the opposite side, and the failure of the membrane will be prevented.

DESCRIPTION OF DRAWINGS

Figure 1 is a detailed perspective view of a nitrogen heat exchanger with an integrated expansion tank, in accordance with the prior art.

Figure 2 is a view of the state in which the elastic bag of Figure 1 passes through the communication holes available in the partition and enters there.

Figure 3 is a detailed perspective view of a heat exchanger with an integrated expansion tank, in accordance with the present invention.

Figure 4 is an assembled state of a heat exchanger with an integrated expansion tank in accordance with the present invention.

Figure 5 is a partial enlarged view of the assembled state of the heat exchanger with an integrated expansion tank, in accordance with the present invention.

Figure 6 is a partial view of a partition wall of a heat exchanger with an integrated expansion tank, in accordance with the present invention.

Figure 7 is a view in cross section made along the direction aa 'in figure 6.

Figure 8 is a partial enlarged view, in an expanded state, of a heat exchanger membrane with an integrated expansion tank, in accordance with the present invention.

Figure 9 is an assembled state of a hot water heat exchanger pipe of a heat exchanger with an integrated expansion tank, in accordance with the present invention.

Figure 10 is an assembled state of a heat exchanger membrane with an integrated expansion tank in accordance with the present invention.

MODES FOR CARRYING OUT THE INVENTION

Hereinafter, a heat exchanger with an integrated expansion tank, and a boiler including them, in accordance with exemplary embodiments of the present invention, together with the accompanying drawings, are described in detail.

First of all, as shown in figure 3, the heat exchanger 200 with an integrated expansion tank, in accordance with the present invention, includes a casing 210 of the water chamber, the casing 210 of the gas chamber, a baffle 230, a heat exchanger tube 240 of hot water, and a membrane 250. Each of configurations of this is assembled, as shown in figure 4.

Thus, the casing 210 of the water chamber and the casing 210 of the gas chamber are mated so as to face each other, thus constituting one “heat exchanger casing”, and there is a partition 230, in the casing of the heat exchanger, with the separation of the casing into the water chamber and the gas chamber.

In addition, a hot water heat exchanger tube 240, for hot water of the heat exchanger, is installed in the water chamber, and a closed-type expansion tank membrane 250 is installed in the gas chamber, thereby forming a heat exchanger with an integrated expansion tank.

In addition, as will be described in more detail below, the specific water-shaped openings of the mains water flow holes 232 are located in the baffle 230, and several support projections 232b and 232c are arranged around the mains water flow openings 232, so that the deformation of the membrane 250 can be prevented , and the reliability of the device in operation is increased.

In more detail, one side of the casing 210 of the water chamber is open, and the casing 210 of the water chamber includes a water chamber within which network water flows. Thus, the water chamber is formed in a space surrounded by the surfaces of the inner wall of the casing 210 of the water chamber.

In addition, in the casing 210 of the water chamber there is a network water inlet 211, a network water outlet 212, a straight-through water inlet 213 and a hot water outlet 214, and, if necessary, the water chamber casing 210 includes an AV duct.

In one example, the inlet pipe 211 of the network water is connected to one side of the casing 210 of the water chamber, and the outlet pipe 212 of the network water is connected to the other side opposite to that one side of the casing 210 of the water chamber. The inlet pipe 213 of the once-through water and the outlet pipe 214 of the hot water are connected to a side surface on which there is a outlet pipe 212 of the network water.

The inlet pipe 211 of the network water and the outlet pipe 212 of the network water communicate with the water chamber inside the casing 210 of the water chamber, and the circulation pipe of the network water (not shown) of the boiler is connected to the inlet pipe 211 of the network water and the outlet pipe 212 of the network water. Thus, the high-temperature network water through the inlet pipe 211 network water passes through the water chamber and is then discharged through the outlet pipe 212 network water.

Thus, the high-temperature network water exchanges heat with the hot water heat exchange pipe 240 installed in the water chamber, and the once-through water that circulates through the hot water heat exchange pipe 240 is heated so that the hot water can always be ready.

The inlet pipe 213 of the once-through water and the outlet pipe 214 of the hot water also communicate with the water chamber inside the casing 210 of the water chamber, and both ends of the heat exchanger pipe 240 of hot water are inserted and mated with the inlet pipe 213 of the once-through water and the outlet pipe 214 of hot water inside the casing 210 of water cameras.

Preferably, however, there is a pressure matching portion 210b on the upper surface of the casing 210 of the water chamber protruding outward. In one example, the pressure matching portion 210b is approximately oval in the center of the casing 210 of the water chamber.

Thus, since the volume of the water chamber is increased by the pressure matching portion 210b, due to the pressure matching portion 210b, when a large amount of mains water quickly flows into the water chamber casing 210, the water chamber casing 210 is not damaged even under pressure when the water is hit.

There is an airborne portion 210a in the lower portion of the water chamber casing 210, which is used when the water chamber casing 210 is connected to the gas chamber casing 210, as will be described below.

The casing 210 of the gas chamber is assembled so as to face the casing 210 of the water chamber. The assembly method is not restrictive, and in one example, an airborne portion 210a of the casing 210 of the water chamber is inserted into and fastened from within the airborne section 220a of the casing 210 of the gas chamber.

The casing 210 of the gas chamber has one open side, like the casing 210 of the water chamber, and includes a gas chamber. Thus, the gas chamber is formed in a space surrounded by the inner surfaces of the wall of the casing 210 of the gas chamber.

In addition, there is a gas injection port 221 on one side of the gas chamber case 210. Such a gas injection port 221 is designed to communicate with the gas chamber so that gas, such as nitrogen, etc., can be pumped through the gas injection port 221.

Thus, when gas is pumped into the gas chamber so that the gas chamber inside the gas chamber casing 210 is at the desired pressure, the membrane 250, which will be described later, expands towards the partition 230.

On the other hand, when the temperature of the mains water rises and the pressure of the boiler pipe becomes higher than the pressure in the gas chamber, the mains water flows into the gas chamber through the openings 232 of the mains water flow of the partition 230. In this case, the mains water pushes the expanded membrane 250 and flows into the gas chamber, and thus absorbs the shock.

However, as shown in FIG. 5, there is a bend such that the end of the baffle 230 bends outward, and the bend is made such that the end of the casing 210 of the gas chamber bends inward, and the end of the membrane 250 bends outward, and the membrane 250 is inserted between these bends during assembly .

Thus, when the shape of the compressed portion of the membrane 250 and the shape of the compressed portion of the contact of the casing 210 of the gas chamber are deflected outward, the volume of the membrane 250, which is compressed and expands during the bending operation, must expand outward so that upon completion of the compression process, the membrane 250 is not leaves the casing 210 of the gas chamber.

In addition, the expandable membrane 250 is in close contact with the side surfaces of the gas chamber and the floor surface of the water chamber, thereby maximizing the tightness, and when installing the membrane 250 in the water chamber, the membrane does not exit the water chamber, so the membrane 250 cannot to leave the water chamber during its movement during operation.

There is a partition 230 in the demarcation area between the water chamber and the gas chamber in the casing of the heat exchanger. For example, the membrane 250 is placed on the casing 210 of the gas chamber, and the baffle 230 is inserted in the upper portion of the membrane 250, and the casing 210 of the water chamber, with the heat exchange pipe 240 of hot water therein, is mounted on the baffle 230; thus, inside the casing of the heat exchanger is divided.

A portion of the insert 230a that guides the insert of the membrane 250 protrudes downward along the edges of the lower portion of the baffle 230 and there are peeling protrusions 231 on the surface of the baffle 230; openings 232 of the flow of network water are all located in a specific area of one side surface of the protrusion 231 peeling.

In this case, however, at least one or more peeling protrusions 231 may be provided on the lower surface of the septum 230 on which the membrane 250 is provided. In FIG. 3, the upper surface of the septum 230 is compressed, so the peeling protrusions 231 protrude in the direction of the lower surface of the septum 230 .

In addition, peeling protrusions 231 are linear in the width direction of the partition 230, and are spaced at regular intervals along the length of the partition 230.

Therefore, even when the membrane 250 expands and remains in contact with the baffle 230 for a long time, the membrane 250 is easily separated from the baffle 230 due to peeling protrusions 231. This effect is achieved due to the fact that the contact area between the membrane 250 and the baffle 230 is reduced due to the protrusions 231 peeling.

In the prior art, the membrane 250 expands due to gas, and is in close contact with the baffle 230, and when this condition persists for a long time, an elastic bag of rubber material adheres to the surface of the baffle 230.

Thus, even when the temperature of the network water rises and the pressure of the network water increases due to an increase in its volume, the membrane 250 adheres to the septum 230, and the network water pushes the membrane 250, and is not discharged in the direction of the gas chamber.

In addition, since the flow of network water entering the water chamber changes direction and forms a whirlpool, peeling protrusions 231 also contribute to improving the efficiency of heat exchange with the hot water heat exchange tube 240 installed in the water chamber.

Further, the network water flows from the water chamber to the gas chamber through the openings 232 of the network water stream of the partition wall 230. Thus, when the pressure in the boiler pipe increases, the network water flows into the gas chamber from the water chamber and absorbs the shock caused by the pressure change. When the pressure of the boiler pipe decreases due to the pressure of the gas chamber, the supply water in the gas chamber is repeatedly discharged in the direction of the water chamber.

In particular, there are a plurality of openings 232 for the flow of network water in accordance with the present invention. In this case, there are many openings 232 of the network water flow in a specific area of the side surface of the partition 230, while the network water is scattered and flows into the water chamber through each of the openings 232 of the network water stream.

As shown in FIG. 6, in one embodiment, a plurality of network water flow openings 232 are provided on the mounting surface 232a of a particular area, circumferentially, at equal intervals. The dividing line of such a specific area may take the form of a circle.

Instead of using one large diameter hole for the network water stream (see Figure 2), as in the prior art, in the present invention there are several network water stream openings 232, each of which has a small diameter, and together they are in a specific area.

Thus, in accordance with the present invention, the inflow of network water at the same rate is possible, and the expanding membrane 250 can be reliably prevented from entering the openings 250 of the network water stream, or being extruded in the opposite direction.

Therefore, in accordance with the present invention, the membrane 250 is protected from deformation and loss of function, and the membrane 250 is protected from getting into the holes 232 of the network water stream, and the holes 232 of the network water stream are protected from clogging.

In addition, as shown in FIG. 7, preferably, the first abutment protrusion 232b protrudes from the bottom surface of the partition 230 along the boundary line of a specific area. Since the bottom surface of the membrane 230 is the surface on which the membrane 250 is located, the first abutment protrusion 232b supports the membrane 250.

Thus, when the first abutment protrusion 232b supports the membrane 250, and in a particular area there are a plurality of network water flow openings 232, each small in size, as described above, the membrane 250 is protected against penetration of the network water flow openings 232.

In addition, when the expandable membrane 250 is in contact with the first abutment protrusion 232b, a sealing portion is formed at the point of contact between the membrane 250 and the first abutment protrusion 232b, so the mains water cannot flow into the gas chamber in the normal state in which the pipe pressure no higher than the pressure of the gas chamber.

In addition, preferably, the second support protrusion 232c protrudes between the network water flow openings 232 of the lower surface of the partition wall 230. Thus, the entire perimeter of each of the network water flow openings 232 is surrounded by a first support protrusion 232b and a second support protrusion 232c.

If there is a first support protrusion 232b on the boundary line of a particular area around the openings of the network water flow, and there is a second support protrusion 232c between the openings 232 of the network water stream, the perimeter of each of the holes 232 of the stream has a design with a slope upward (see arrow).

Therefore, as shown in FIG. 8, the expandable membrane 250 rests on the first abutment protrusion 232b and the second abutment protrusion 232c, and is not inserted into the openings 232 of the mains water flow, and thus, the deformation of the membrane 250 is prevented and its smooth operation is guaranteed.

However, the above-described first abutment protrusion 232b and the second abutment protrusion 232c can be continuous, and can also be performed at regular intervals, while maintaining their patterns. For example, the first abutment protrusion 232b may also be made at regular intervals around the circumference, rather than being made continuous around the circumference.

At the same time, the hot water heat exchanger pipe 240 prepares the hot water at a suitable temperature when preparing for the use of hot water by the user, so that cold water cannot be supplied at the start of the use of hot water, and a delay in the supply of hot water is prevented.

For this purpose, a hot water heat exchange pipe 240 is installed between the baffle 230 and the water chamber. Thus, the hot water heat exchange pipe 240 is installed in the casing 210 of the water chamber, and has the form of a coil with many turns, while the length of the stream passing through it increases, and the heat exchange is carried out for a sufficient time.

In addition, as shown in FIG. 9, an inlet pipe 241 at the end of one side of the hot water heat exchanger pipe 240 is inserted into the inlet pipe 213 of the once-through water of the casing 210 of the water chamber, and the outlet pipe 242 at the end on the other side opposite such one side is inserted into a hot water discharge port 214 of the casing 210 of the water chamber.

Therefore, if the once-through water pipe (not shown) is connected to the in-line water inlet 213 and the hot water pipe (not shown) is connected to the hot-water outlet 214, low-temperature once-through water supplied by the once-through water pipe is supplied to the inlet pipe 241 of the heat exchange pipes of hot water 240.

While the once-through water supplied to the hot-water heat exchange pipe 240 circulates in the hot-water heat exchange pipe 240, heat is exchanged between the once-through water and the high-temperature network water in the water chamber, and the once-through water becomes hot. Such hot water is discharged in the direction of the hot water pipe by means of the outlet pipe 242 of the hot water heat exchange pipe 240.

The membrane 250, which is an elastic bag of elastic material, expands due to the injection of gas (for example, gaseous nitrogen), at a given pressure into the gas chamber, and serves as a closed expansion tank.

The membrane 250 is installed between the partition 230 and the gas chamber. Thus, the membrane 250 is installed in the casing 210 of the gas chamber.

In addition, as shown in FIG. 10, the membrane 250 has a cap shape that covers a completely open upper portion of the gas chamber case 210, for example, and includes an upper expansion portion 250a and a lower connection portion 250b, as shown in FIG. 3.

Thus, when the pressure of the supply water is lower than the pressure of the gas chamber, the membrane 250 remains in the expanded state in the direction of the partition 230. On the other hand, when the pressure of the supply water is higher than the pressure of the gas chamber, the membrane 250 passes through the partition 230 in the water chamber and reduced by the action of network water, which flows into the gas chamber.

Hereinafter, a boiler is described including a heat exchanger 200 with an integrated expansion tank, in the above configuration, in accordance with the present invention.

The boiler in accordance with the present invention is characterized by the presence of a heat exchanger 200 with an integrated expansion tank, with the above configuration, and other well-known issues apply to several types of boilers.

For example, a boiler includes a boiler body, a burner, a main heat exchanger, and a combustion pipe. The above-described burner and main heat exchanger, in addition to the heat exchanger 200 with an integrated expansion tank, in accordance with the present invention, are installed in the boiler body. The combustion pipe discharges the combustible gas generated during the burning of the burner to the outside.

In addition, the network water supply pipe is connected to the network water inlet 211 of the heat exchanger 200 with an integrated expansion tank, and the network water discharge pipe is connected to the network water outlet 212. In addition, the network water supply pipe is connected to the main heat exchanger, and the network water discharge pipe extends to the heating space.

Thus, thanks to the flame ignited during ignition of the burner and the high temperature combustion gas, heating the circulating water that flows into the main heat exchanger results in high temperature network water and high temperature network water is supplied to the water chamber of the heat exchanger 200 with an integrated expansion tank through the pipe supply of network water.

In addition, the high-temperature network water supplied to the water chamber of the heat exchanger 200 with an integrated expansion tank exchanges heat with the low-temperature direct-flow water that flows in the hot water heat exchanger pipe 240 installed in the water chamber and becomes hot water, and such hot water is discharged by hot water pipes.

Industrial applicability

While the invention has been shown and described with reference to some exemplary embodiments, those skilled in the art understand that various changes in form and details can be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. .

Thus, since the above embodiments are presented to fully inform those skilled in the art about the scope of the invention, those skilled in the art understand that the embodiments are illustrative in all aspects and are not restrictive, and the present invention is defined only by the claims.

Claims (11)

1. A heat exchanger with an integrated expansion tank, comprising: a casing (210) of the water chamber, inside which there is a water chamber, within which network water flows, containing an inlet pipe (211) of network water through which the supply of network water is provided, an outlet pipe (212) of network water through which the network water is discharged , an inlet pipe (213) of once-through water, through which an influx of once-through water is provided, and an outlet pipe (214) of hot water through which a discharge of hot water is provided; the casing of the gas chamber (210), facing the casing (210) of the water chamber, with the formation of a single casing of the heat exchanger, and having a gas chamber inside; a partition (230) located inside the heat exchanger casing, in the demarcation section between the water chamber and the gas chamber, with a certain area on one side surface, in which there are many holes (232) for the flow of network water, providing dispersion of network water and its inflow; a hot water heat exchange pipe (240) located between one side surface of the partition (230) and the water chamber, with an inlet pipe (241) at the end of one of its sides inserted into the inlet pipe (213) of the once-through water of the casing (210) of the water chamber, and an outlet pipe (242) at the end of its other side inserted into the outlet pipe (214) of hot water of the casing (210) of the water chamber; and a membrane (250) located between the gas chamber and the other side surface of the partition (230), configured to expand due to the expansion gas entering the gas chamber, or compression due to the flow of network water into the gas chamber through the openings (232) of the network water stream, wherein the first abutment protrusion (232b) protrudes from the plane of the lower surface of the septum (230), in which the membrane (250) is located, along the boundary line of a certain area. 2. A heat exchanger with an integrated expansion tank according to claim 1, characterized in that the second support protrusion (232c) protrudes between the openings (232) of the network water stream of the lower surface of the partition (230). 3. A heat exchanger with an integrated expansion tank according to claim 2, characterized in that the plurality of openings (232) of the network water stream are made in a certain area, circumferentially, at equal intervals, and the dividing line of such a specific area can be in the form of a circle. 4. A heat exchanger with an integrated expansion tank according to claim 1, characterized in that at least one or more peaks (231) of delamination protrude from the plane of the lower surface of the partition (230), where the membrane (250) is located. 5. A heat exchanger with an integrated expansion tank according to claim 1, characterized in that there is a bend so that the end of the partition (230) is bent outward and there is a bend so that the end of the casing (210) of the gas chamber is bent inward and the end of the membrane (250) is bent outward, and the membrane (250) is placed between the bend of the partition (230) and the bend of the casing (210) of the gas chamber. 6. A boiler containing a heat exchanger with an integrated expansion tank according to any one of paragraphs. 1-5.

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