KR102145254B1 - Multi-purpose electric boiler using finless type multi-pipe double pipe heat exchanger - Google Patents

Abstract

The present invention relates to the manufacture of an electric boiler using a finless type multi-tube double tube heat exchanger. More specifically, an electric heater is inserted into an inner pipe using a separate double tube heat transfer surface of a heat exchanger, and a gap between the inner pipe and the outer pipe is used. The heat transfer medium is heated, and the heated heat medium heats the outer pipe heat transfer surface to produce hot water using the outer pipe heat transfer surface or heat the gas to generate hot air to increase the efficiency and convenience of use of the heat exchanger. It relates to an electric boiler using a finless type multi-tube double tube heat exchanger for ease of use.

Description

Multi-purpose electric boiler using finless multi-pipe double pipe heat exchanger{omitted}

The present invention relates to the manufacture of an electric boiler using a finless type multi-tube double tube heat exchanger. More specifically, an electric heater is inserted into an inner pipe using a separate double tube heat transfer surface of a heat exchanger, and a gap between the inner pipe and the outer pipe is used. The heat transfer medium is heated, and the heated heat medium heats the outer pipe heat transfer surface to produce hot water using the outer pipe heat transfer surface or heat the gas to generate hot air to increase the efficiency and convenience of use of the heat exchanger. It relates to an electric boiler using a finless type multi-tube double tube heat exchanger for ease of use.

In general, electric boilers heat cold water introduced through a water supply pipe through an electric heater to make hot water, and are divided into hot water boilers and storage boilers according to the method of heating hot water.

However, such general hot water type electric boiler and storage type electric boiler are used when heating or producing hot water. The hot water supply type requires an excessive heater capacity, or the storage type requires a long heating time and requires a large space for an excessive size, making it difficult to install and increasing heating costs.

Therefore, in order to solve this problem, as a related prior technology, as shown in a hot water and heating boiler having a double-pipe structure of Patent No. 10-0690278, a double-pipe structure of the inner pipe and the outer pipe is made, and the heater as a heat source is placed in the inner pipe, Was made to flow between the inner pipe and the outer pipe and to heat hot water through the outer pipe.

The present applicant and the present applicant also proposed a heat exchange device having a double tube structure of “Finless Type Double Tube Heat Exchanger” and Registered Patent No. 10-1672278 “Boiler Finless Type Multiple Tube Heat Exchanger”.

However, the double-pipe electric boiler according to the prior art is designed to produce hot water by simply arranging these pipes and exchanging heat with steam.Therefore, since there is no chamber for accommodating the heat exchange pipes in bundles, the thermal efficiency is dispersed and the inside and outside of the double pipe are separated The heat transfer surface is not being used effectively.

The present invention is an invention conceived to solve the conventional problem as described above, and an electric heater is inserted into the inner pipe using a double tube heat transfer surface separated by space, and the heat medium flowing between the inner pipe and the outer pipe is heated and heated. The heat transfer medium heats the outer pipe heat transfer surface and uses the outer pipe heat transfer surface to produce hot water or heats the gas to generate warm air to allow indoor heating, thereby increasing the efficiency of the heat exchanger and making it easier to use. The purpose of this is to provide a multi-purpose electric boiler using a multi-pipe double-pipe heat exchanger.

In the present invention for achieving such an object, the present invention is to receive heating water from the heating inlet 162 connected to the heating water circulation pipe 160 and discharge the heated water through the heating water outlet 161 One chamber 141; A plurality of outer pipes 143 connected to the outside of the inner wall of the first chamber 141; A second chamber 142 connected through the ends of the plurality of outer pipes 143; A heater 150 for heating the heat medium is inserted into the hollow, and one end is penetrated to the outer wall of the first chamber 141 and the other end extends to the second chamber 142 to meet the outer pipe 143. A plurality of inner pipes 144 forming a heat medium flow path therebetween to allow the heat medium to flow between the first chamber 141 and the second chamber 142; A first coupling body 151 fixed to one end of the inner pipe 144 to mediate a coupling between the inner pipe 144 and the outer wall of the first chamber 141; And a second assembly 152 fixed to the outer wall of the first chamber 141 and surrounding and coupling the outer circumferential surface of the first assembly 151; the first chamber 141 of the heat exchanger 140 comprising: And a plurality of outer pipes 143 exposed between the and the second chamber 142 are accommodated, and a water inlet 121 for hot water is formed at the top, and a hot water outlet 122 is formed at the bottom to generate hot water. Including a third chamber 120, the coupling between the outer circumferential surface of the first coupling body 151 and the inner circumferential surface of the second coupling body 152 is by screwing, and the first chamber 141 and the second chamber A partition wall 145 that divides the space of 142 into a plurality of spaces is formed so that the heat medium flows sequentially between the first chamber 141, the heat medium flow path, and the second chamber 142 to heat the heat medium. The plurality of heaters 150 of the heat exchanger 140 installed in the third chamber 120 are arranged in a horizontal direction, so that the heat of the heat medium on the heat medium flow path passes through the outer pipe 143. The hot water in the third chamber 120 is circulated and heated by natural convection by being transferred to the water introduced from the water inlet 121.
When the inner pipe is coupled, the second assembly includes a first region having a first diameter in cross section of the inner circumferential surface so as to surround the outer circumferential surface of the first assembly, extending from the first region and limiting movement of the first assembly. A second region having a second diameter smaller than the first diameter in cross section is formed at an end portion to which the first assembly is connected.

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In addition, the second region includes a sealing portion provided in the insertion space so as to be located between the inner end of the first assembly facing each other in a linear direction and the end of the second assembly, and the sealing portion is at least one O-ring or one The abnormal gasket is inserted.

The first coupling body of the inner pipe inserted through the second coupling body attached to the outer wall of the first chamber is rotated and closely contacted with the inner pipe coupling bolt or nut from the outside of the first chamber through the threads formed on both sides. As furnace pressure is applied to compress the O-ring or gasket in the sealing part, the bonding and sealing of the connected inner pipe connection part of the first chamber are performed at the same time.

In addition, a box-shaped third chamber that accommodates a plurality of outer pipe outer circumferential surfaces exposed between the first chamber and the second chamber is constructed, and the outer pipe exposed surface of the heat exchanger is accommodated at the lower part, and the inner pipe (heater) When the heat medium flowing between the inner pipe and the outer pipe is heated and the heat medium heats the outer pipe, the heat medium in the third chamber is heated, and the heat medium is circulated and heated by convection.

As an example related to the present invention, the first assembly coupled to the plurality of inner pipes and the second assembly coupled through the outer wall of the first chamber are connected by welding.

As an example related to the present invention, the first assembly and the first chamber coupled with the plurality of inner pipes are threaded corresponding to one end of which the first assembly and the first chamber are coupled to each other for screwing with each other in order to screw with each other in order to bind and seal the second assembly through the outer wall Is formed.

The assembly method of the assembly for achieving the object of the present invention is the step of welding one end of the inner pipe (heater) first assembly provided with the heating source and one end of the inner pipe, and the outer peripheral surface of the first assembly Through-welding one end of the second coupling body formed to be coupled to the outer wall of the first chamber, the first coupling body coupled to one end of the inner pipe into the inside of the second coupling body penetrating through the first chamber and the outer wall Inserting and screwing the first assembly and bolts, and coupling a third box-shaped chamber accommodating the outer peripheral surfaces of the plurality of outer pipes with a heat exchanger.

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The present invention as described above is an invention conceived to solve the conventional problem as described above, and for this purpose, an electric heater is inserted into the inner pipe using a double pipe heat transfer surface separated by space, and flows between the inner pipe and the outer pipe. The heat medium is heated and the heated heat medium heats the outer pipe heat transfer surface to produce hot water using the outer pipe heat transfer surface or heat the gas to generate hot air to increase the efficiency and ease of use of the heat exchanger. It is a very useful invention for living environments by providing an electric boiler using a finless type multi-tube double tube heat exchanger.

1 is a front view (a) and a plan view (b) of an electric boiler for heating hot water according to the present invention;
Figure 2 is a perspective view showing the inner body assembly structure of the electric boiler for heating and hot water according to an embodiment of the present invention from two directions;
3 is a left sectional view showing natural convection of hot water using a heat medium in a heat exchanger of an electric boiler for heating hot water according to an embodiment of the present invention;
Figure 4 is a front view (a), a plan view (b), a left side view (c) of the inner body assembly structure of the electric boiler for heating and hot water according to an embodiment of the present invention;
5 is a BB cross-sectional view (a), a plan view (b), a partial cross-sectional view (c) of the inner body assembly structure of the electric boiler for heating and hot water according to another embodiment of the present invention;
6 is an exploded perspective view (a) and an assembled perspective view (b) showing the structure of a heat exchanger for an electric boiler according to an embodiment of the present invention;
7 is a cross-sectional view showing a heat medium circulation structure of a heat exchanger for an electric boiler according to an embodiment of the present invention;
8 is a cross-sectional view showing a detailed structure of a heat exchanger according to an embodiment of the present invention;
9 is a front view (a), a right cross-sectional view (b), and a plan view (c) showing a structure of an electric boiler for heating and hot air according to another embodiment of the present invention;
10 is a perspective view showing a body assembly structure of an electric boiler for heating and hot air according to another embodiment of the present invention from two directions;
11 is a cross-sectional view showing a heat medium circulation path in a heat exchanger and a gas circulation path using a blower of an electric boiler for heating and hot air according to another embodiment of the present invention;
12 is a front view (a), a top view (b), a left side view (c) of the body assembly structure of the electric boiler for heating and hot air according to another embodiment of the present invention;
13 is a rear cross-sectional view (a), a plan cross-sectional view (b), and a right cross-sectional view (c) of the body assembly structure of the electric boiler for both heating and air according to another embodiment of the present invention.

Hereinafter, a multi-purpose electric boiler using the finless type multi-tubular double-pipe heat exchanger according to the present invention will be described in more detail with reference to the drawings.

Prior to describing in more detail the multi-purpose electric boiler using the finless type multi-tubular dual-pipe heat exchanger of the present invention,

The present invention will be described in detail in the text of the bar, implementation (態樣, aspect) (or embodiment) that can apply various changes and have various forms. However, this is not intended to limit the present invention to a specific form of disclosure, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

In each drawing, the same reference numerals, in particular the number of tens and ones, or the same reference numerals with the same tens, ones, and alphabet indicate members having the same or similar functions, and unless otherwise specified, each of the drawings The member indicated by the reference number can be identified as a member conforming to these criteria.

In addition, the components in each drawing are expressed by exaggeratingly large (or thick) or small (or thin) or simplified the size or thickness in consideration of the convenience of understanding, but this limits the scope of protection of the present invention. It shouldn't be.

The terms used in the present specification are only used to describe specific embodiments (sun, 態樣, aspect) (or embodiments), and are not intended to limit the present invention.

Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as ~include~ or ~consist~ are intended to designate the presence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other features It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being added.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.
1 to 8 are views showing an electric boiler for both heating and hot water according to an embodiment of the present invention.

As shown in FIG. 8, the electric boiler using the finless type multi-pipe type double pipe heat exchanger receives heating water from the heating inlet 162 connected to the heating water circulation pipe 160 and warms it through the heating outlet 161. The first chamber 141 for discharging the heating water, a plurality of outer pipes 143 connected to the outside of the inner wall of the first chamber 141, a second chamber connected through the ends of the plurality of outer pipes 143 ( 142), a heater 150 for heating the heat medium is inserted into the hollow, one end is penetrated to the outer wall of the first chamber 141, and the other end extends to the second chamber 142 to extend the outer pipe ( A plurality of inner pipes 144 to form a heat medium flow path between the first chamber 141 and the second chamber 142 to allow the heat medium to flow between the first chamber 141 and the second chamber 142, fixed to one end of the inner pipe 144 A first coupling body 151 that mediates the coupling between the inner pipe 144 and the outer wall of the first chamber 141, and the first coupling body 151 being fixed to the outer wall of the first chamber 141 A plurality of outer pipes 143 exposed between the first chamber 141 and the second chamber 142 of the heat exchanger 140 composed of a second assembly 152 for bonding while surrounding the outer peripheral surface of A water inlet 162 for hot water is formed at the upper end, and a hot water outlet 122 is formed at the lower end to include a third chamber 120 for generating hot water, and the outer circumferential surface of the first assembly 151 and the The coupling between the inner circumferential surfaces of the second assembly 152 is screwed, and a partition wall 145 that divides the spaces of the first chamber 141 and the second chamber 142 into a plurality of spaces is formed. A plurality of heaters of the heat exchanger 140 installed in the third chamber 120 are heated while the heat medium flows sequentially between the first chamber 141, the heat medium flow path, and the second chamber 142 150 are arranged side by side in the horizontal direction, the heat medium on the heat medium flow path The heat of is transferred to the water introduced from the water inlet 162 via the outer pipe 143 to circulate and heat the hot water in the third chamber 120 by natural convection.
The second assembly 152 is a first region having a first diameter in cross section of the inner circumferential surface so as to surround the outer circumferential surface of the first assembly 151, extending from the first region, and limiting movement of the first assembly 151 The cross section of the inner circumferential surface has a second diameter smaller than the first diameter so that a second region is formed at an end portion to which the first assembly 151 is connected.

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In addition, it includes a sealing portion provided in the insertion space so as to be positioned between the inner end of the first coupling body 151 and the end of the second coupling body 152 facing each other in a linear direction in the second region, and at least one O-ring or One or more gaskets are inserted.

The first coupling body 151 of the inner pipe 144 inserted through the second coupling body 152 attached to the outer wall of the first chamber 141 is formed from the outside of the first chamber 141 through threads formed on both sides. The inner pipe 144 connected to the inner pipe 144 of the first chamber 141 is compressed by applying pressure to the binding ends of the coupling bodies 151 and 152 by rotating and closely contacting the inner pipe 144 with a bolt or nut for coupling. ) Bonding and sealing of the connection are performed at the same time.

In addition, it includes a box-shaped third chamber 120 surrounding the outer circumferential surface of a plurality of outer pipes 143 exposed between the first chamber 141 and the second chamber 142, and the third chamber heat-exchanges at the bottom. It accommodates a plurality of outer pipes 143 exposed surfaces.

The heater 150 heats the heat medium flowing between the inner pipe 144 and the outer pipe 143, and when the heat medium heats the outer pipe 143, the heat medium (hot water) in the third chamber 120 is heated. The heating medium (hot water) is circulated and heated by natural convection as shown in FIG. 3.

As an example related to the present invention, between the first assembly 151 coupled with the plurality of inner pipes and the first chamber 141, and the second assembly 152 coupled through the outer wall are connected by welding.

As an example related to the present invention, the first assembly 151 and the first chamber 141 coupled with the plurality of inner pipes 144 are coupled and sealed of the second assembly 152 through the outer wall. In order to do so, a thread corresponding to one end portion which is bound to each other is formed.

The assembly method for achieving the object of the present invention is the step of welding one end of the inner pipe 144 provided with the heating source with one end of the first assembly 151, and the outer peripheral surface of the first assembly 151 And penetrating one end of the second coupling body 152 formed to be coupled to the outer wall of the first chamber 141.

Insert the first coupling body 151 coupled with both ends of the inner pipe 144 into the inside of the second coupling body 151 coupled through the outer wall of the first chamber 141, and the bolt of the first coupling body 151 It includes the step of screwing into, and coupling a third box-shaped chamber 120 accommodating the outer peripheral surface of the plurality of outer pipes 143 with a heat exchanger.

9 to 13 show another electric boiler for both heating and warm air according to another embodiment of the present invention.
Referring to the drawings, in the electric boiler for both heating and hot air according to the present embodiment, in the above-described embodiment, a heat medium (heating water) heats hot water, and as shown in FIG. 11, the fourth chamber 172 is a heat exchanger. Instead of accommodating 140 to the side, it is installed vertically and accommodated, and the blower 170 is placed at the rear end of the lower rear end of the fourth chamber 172 accommodating the heat exchanger 140 to the inside of the receiving portion of the third chamber. Air is supplied to exchange heat with the outer sides of the plurality of outer pipes 143 inside the heat exchanger 140 and then discharged through the air discharge duct 173 installed on the upper front part of the fourth chamber 172.

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As an example related to the present invention, the plurality of inner pipes 144, the first coupling body 151, between the first chamber 141, and the second coupling body 152 penetrated through the outer wall is connected by a welding method. do.

As an example related to the present invention, the first coupling body 151 and the first chamber 141 coupled with the plurality of inner pipes 144 are coupled to the second coupling body 152 through the outer wall. A thread corresponding to one end that is bound to each other is formed for coupling.

The assembling method for achieving the object of the present invention includes preparing an inner pipe 144 having the heating source, and welding one end of the first assembly 151 and one end of the inner pipe 144 , And penetrating one end of the second assembly 152 formed to be coupled to the outer circumferential surface of the first assembly 151 to the outer wall of the first chamber 141.

Inserting the first assembly 151 coupled to one side of the inner pipe 144 into the inside of the second assembly 152 coupled through the outer wall of the first chamber 141, and screwing the first assembly with a bolt It includes the step of.

A heat exchanger 140 is accommodated in a box-shaped fourth chamber 172 accommodating the outer circumference of the plurality of outer pipes 143, and a blower 170 is located at the lower rear end of the fourth chamber 172 accommodating the heat exchanger 140 And coupling the air discharge duct 173 to the upper front part of the fourth chamber 172 for discharging the air inside the fourth chamber 172 to the outside.

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In the above description of the present invention, an electric boiler using a finless type multi-tubular dual-pipe heat exchanger having a specific shape and structure has been described with reference to the accompanying drawings, but the present invention can be variously modified and changed by those skilled in the art. These modifications and changes should be construed as belonging to the scope of the present invention.

<Name of symbols for major parts of drawings>
100: electric boiler body
110: water tank for heating
120: third chamber
121: water inlet for hot water 122: hot water outlet
130: pump
140: heat exchanger 141: first chamber 142: second chamber
143: outer pipe
144: inner pipe
145: bulkhead
150: electric heater 151: first assembly 152: second assembly
160: heating water circulation pipe 161: heating outlet 162: heating intake
170: hot air blower 171: air inlet duct
172: fourth chamber
173: air exhaust duct

Claims (5)

A first chamber 141 receiving heating water from the heating inlet 162 connected to the heating water circulation pipe 160 and discharging the heated heating water through the heating water outlet 161;
A plurality of outer pipes 143 connected to the outside of the inner wall of the first chamber 141;
A second chamber 142 connected through the ends of the plurality of outer pipes 143;
A heater 150 for heating the heat medium is inserted into the hollow, and one end is penetrated to the outer wall of the first chamber 141 and the other end extends to the second chamber 142 to meet the outer pipe 143. A plurality of inner pipes 144 forming a heat medium flow path therebetween to allow the heat medium to flow between the first chamber 141 and the second chamber 142;
A first coupling body 151 fixed to one end of the inner pipe 144 to mediate a coupling between the inner pipe 144 and the outer wall of the first chamber 141; And
A second assembly 152 fixed to the outer wall of the first chamber 141 and surrounding and coupling the outer circumferential surface of the first assembly 151;
A plurality of outer pipes 143 exposed between the first chamber 141 and the second chamber 142 of the heat exchanger 140 are accommodated, and a water inlet 121 for hot water is formed at the top. And, a hot water outlet 122 is formed at the bottom and includes a third chamber 120 for generating hot water,
The coupling between the outer circumferential surface of the first coupling body 151 and the inner circumferential surface of the second coupling body 152 is by screwing,
A partition wall 145 that divides the spaces of the first chamber 141 and the second chamber 142 into a plurality of spaces is formed so that the first chamber 141, the heat medium flow path, and the second chamber 142 ) The heating medium is heated as the heating medium flows sequentially,
The plurality of heaters 150 of the heat exchanger 140 installed in the third chamber 120 are arranged side by side in a horizontal direction, so that the heat of the heat medium on the heat medium flow path passes through the outer pipe 143 to the water inlet A multi-purpose electric boiler using a finless type multi-tube double tube heat exchanger, characterized in that the hot water in the third chamber 120 is circulated and heated by natural convection by being transferred to the water introduced from (121). delete As a method for manufacturing a multi-purpose electric boiler using the finless type multi-pipe double pipe heat exchanger of claim 1,
Welding and fixing the first assembly 151 to one end of the inner pipe 144 with the heater 150;
Welding one end of the second assembly 152 screwed to the outer peripheral surface 151 of the first assembly 151 to the outer wall of the first chamber 141;
Insert the inner pipe 144 into the outer pipe 143 through the second coupling body 152 and the first chamber 141, and between the second coupling body 152 and the first coupling body 151 Screwing; And
Accommodating the outer pipe (143) into the interior of the third chamber (120) and coupling the third chamber (120) and the heat exchanger (140);
Multi-purpose electric boiler manufacturing method using a pinless type multi-tube double tube heat exchanger comprising a. A first chamber 141 receiving heating water from the heating inlet 162 connected to the heating water circulation pipe 160 and discharging the heated heating water through the heating water outlet 161;
A plurality of outer pipes 143 connected to the outside of the inner wall of the first chamber 141;
A second chamber 142 connected through the ends of the plurality of outer pipes 143;
A heater 150 for heating the heat medium is inserted into the hollow, and one end is penetrated to the outer wall of the first chamber 141 and the other end extends to the second chamber 142 to meet the outer pipe 143. A plurality of inner pipes 144 forming a heat medium flow path therebetween to allow the heat medium to flow between the first chamber 141 and the second chamber 142;
A first coupling body 151 fixed to one end of the inner pipe 144 to mediate a coupling between the inner pipe 144 and the outer wall of the first chamber 141; And
A second assembly 152 fixed to the outer wall of the first chamber 141 and surrounding and coupling the outer circumferential surface of the first assembly 151;
A plurality of outer pipes 143 exposed between the first chamber 141 and the second chamber 142 of the heat exchanger 140 are accommodated, and external air is supplied from the blower 170 at the lower end. An air inlet duct 171 for receiving is formed, and a fourth chamber 172 in which an air outlet duct 173 for discharging heated air is formed is formed at the upper end,
The coupling between the outer circumferential surface of the first coupling body 151 and the inner circumferential surface of the second coupling body 152 is by screwing,
A partition wall 145 that divides the spaces of the first chamber 141 and the second chamber 142 into a plurality of spaces is formed so that the first chamber 141, the heat medium flow path, and the second chamber 142 ) The heating medium is heated as the heating medium flows sequentially,
The plurality of heaters 150 of the heat exchanger 140 installed in the fourth chamber 172 are arranged in a vertical direction, and the heat of the heat medium on the heat medium flow path passes through the outer pipe 143 to the blower ( 170), the air in the fourth chamber 172 is circulated and heated by natural convection by being transferred to the external air introduced by the method 170). A multi-purpose electric boiler using a finless type multi-tube double tube heat exchanger. As a method for manufacturing a multi-purpose electric boiler using the finless type multi-pipe double pipe heat exchanger of claim 4,
Welding and fixing the first assembly 151 to one end of the inner pipe 144 with the heater 150;
Welding one end of the second assembly 152 screwed to the outer peripheral surface 151 of the first assembly 151 to the outer wall of the first chamber 141;
Insert the inner pipe 144 into the outer pipe 143 through the second coupling body 152 and the first chamber 141, and between the second coupling body 152 and the first coupling body 151 Screwing;
Accommodating the outer pipe (143) into the interior of the fourth chamber (172) and coupling the fourth chamber (172) and the heat exchanger (140);
Installing a blower 170 for supplying external air to one side of the fourth chamber 172;
Coupling an air discharge duct 173 for discharging the air heated inside the fourth chamber 172 to one side of the fourth chamber 172 to the outside;
Multi-purpose electric boiler manufacturing method using a pinless type multi-tube double tube heat exchanger comprising a.

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