KR20140049142A - Heat recovery apparatus for ship - Google Patents

Abstract

Disclosed is a heat recovery apparatus for a ship, which comprises: a heat absorbing unit including a heat absorbing part for recovering heat generated by operating an engine and a cooling part for cooling the heat generated by operating the engine; a first supply line through which a heat medium, which has heat exchanged in the heat absorbing part, flows; a waste heat recovery unit which communicates with the first supply line and which includes a first heat exchanger absorbing the heat recovered by the heat medium; a second supply line for delivering the heat medium, which has heat exchanged in the first heat exchanger, to the heat absorbing part; a bypass line of which each end is connected to the first and the second supply line, respectively, to selectively let the heat medium bypass through the bypass line; a cooler for recovering the heat recovered by the heat medium which flows through a bypass line in the heat absorbing part; and a clear water line which has clear water flowing therein and which separately circulates the clear water inside at least one among the cooling part, the cooler and the waste heat recovery unit.

Description

[0001] Heat Recovery Apparatus for Ship [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ship waste heat recovery apparatus, and more particularly, to a ship waste heat recovery apparatus for recovering heat of exhaust gas discharged from an engine of a ship.

In recent years, as the era of high oil prices has arrived, efforts have been made to improve the energy efficiency of vessels to reduce fuel costs and to secure eco-friendliness of ship operations.

Generally speaking, energy is consumed most of the energy in the propulsion main engine, and about 25% of the fuel consumed for operation of the main engine is discharged into the atmosphere by the exhaust gas. Accordingly, various devices for recovering a part of the heat using such exhaust gas are actively being introduced.

A heat recovery apparatus (boiler) is installed in an exhaust pipe where exhaust gas is exhausted from an engine of a ship according to the related art waste heat recovery apparatus according to the related art, and the heat of the exhaust gas is recovered (isobaric heating) Respectively.

However, the conventional waste heat recovery apparatus has a problem that the heat generated by the engine can not be processed when the heat recovery apparatus is not operated.

Korean Patent Publication No. 10-2010-0035196

[0001] The present invention relates to a ship waste heat recovery apparatus, in which a separate bypass line is provided on a traveling path of a heating medium for absorbing and transmitting heat generated by driving an engine to continuously cool a heating medium, And the heat medium can be continuously absorbed by the heat medium without being affected by the heat medium.

In order to solve the above problems, a ship waste heat recovering apparatus according to the present invention includes a heat absorbing portion for recovering heat generated by driving of an engine, and a cooling portion for cooling heat generated by driving the engine, A first heat exchanger which communicates with the first supply line and absorbs the heat recovered by the heat medium, a first heat exchanger which communicates with the first heat exchanger, A second supply line for transferring the heat-exchanged heat medium to the heat absorber, a bypass line connected to the first supply line and the second supply line at both ends to selectively bypass the heat medium, A cooler for recovering the heat absorbed by the heat medium by the heat medium, and a fresh water flowing inside the cooler, the cooler, the cooler and the waste heat recovery unit Circulating the fresh water in at least one comprises a fresh water line.

Further, the cooler is disposed on the bypass line, and the heat medium moving along the bypass line can be cooled by performing heat exchange with the clear water.

The apparatus may further include a cooling line branched on the second supply line and selectively bypassing the heating medium, wherein the cooling medium is provided to cool the heating medium by heat exchange with the clean water.

The second supply line is provided with a temperature sensor for measuring the temperature of the heating medium. Between the first supply line and the bypass line, the flow of the heating medium is selectively switched between a flow control valve As shown in FIG.

The waste heat recovering unit may include a second heat exchanger for cooling a circulating fluid absorbing heat in the first heat exchanger, wherein the fresh water line is branched in the moving path of the fresh water, So that the circulating fluid can be cooled.

In addition, the waste heat recovery unit may include a second heat exchanger for cooling a circulating fluid absorbing heat in the first heat exchanger, wherein the fresh water line is connected to the second heat exchanger, and the fresh water via the cooler is continuously To cool the circulating fluid in the second heat exchanger.

In addition, the fresh water line can independently circulate the flowing fresh water to each of the cooler and the cooler.

The ship waste heat recovery apparatus according to the present invention has the following effects.

First, an advantage of absorbing the heat generated by the engine without absorbing the heat generated by the operation of the engine and being affected by the operation of the waste heat recovery unit by selectively bypassing the heating medium to be transferred to the waste heat recovery unit have.

Second, a separate flow control valve is provided on the bypass line to regulate the flow rate of the flowing heat medium through the waste heat recovery unit or the cooler, so that the heat medium can be re-supplied to the heat absorbing part at a temperature suitable for the temperature condition required by the engine There is an advantage.

Third, there is an advantage that a fresh water line can be formed with a simple structure by circulating fresh water using a piping provided in a conventional ship.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a schematic view of a waste heat recovery apparatus according to a first embodiment of the present invention;
FIG. 2 is a schematic view showing the construction of a waste heat recovery unit in the waste heat recovery apparatus of FIG. 1; FIG.
FIG. 3 is a view showing a state in which a heat medium having absorbed the heat of the air in the waste heat recovery apparatus of FIG. 1 moves along a bypass line; FIG.
4 is a view showing a configuration in which a heat absorbing portion absorbs heat of an exhaust gas in the waste heat recovering device of Fig. 1;
5 is a schematic view of a waste heat recovery apparatus according to a second embodiment of the present invention;
6 is a view showing a state in which a heat medium having absorbed heat in a heat absorber in the waste heat recovery apparatus of FIG. 5 moves along a bypass line;
FIG. 7 is a view showing a configuration of a waste heat recovery apparatus according to a third embodiment of the present invention; FIG.
8 is a view showing a state in which a heating medium moves along a bypass line and a cooling line in the waste heat recovery apparatus of Fig.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

First Embodiment

1 is a schematic view showing the construction of a waste heat recovery apparatus according to a first embodiment of the present invention, FIG. 2 is a view schematically showing a construction of a waste heat recovery unit in the waste heat recovery apparatus of FIG. 1, And FIG. 4 is a view showing a configuration in which the heat absorbing portion absorbs the heat of the exhaust gas in the waste heat recovering device of FIG. 1. FIG. 4 is a view showing a state in which the heat medium absorbing the heat of the desired air in the waste heat recovering device of FIG. .

The waste heat recovering apparatus of the present invention supplies heat to the various heat consumers of the ship, such as humidification, dehumidification, maintaining the temperature of a specific part of the ship, and the like. As shown in the figure, the waste heat recovery apparatus of the present embodiment is configured to generate new power by using the generated heat by operating a separate cycle using the heat generated from the engine E provided in the ship.

The waste heat recovering apparatus of the present invention includes a heat absorption unit 100, a first supply line 200, a waste heat recovery unit 300, a second supply line 400, a bypass line 500, a cooler 600, (700).

The heat absorbing unit 100 is a structure for recovering or cooling the heat generated in the engine E and specifically includes the engine E itself, the exhaust gas G discharged from the engine E, Thereby recovering or cooling the heat of the supplied noble gas (A). The heat absorbing unit 100 includes a heat absorbing part 110 and a cooling part 120.

The heat absorbing portion 110 is disposed on the exhaust path of the exhaust gas G generated from the engine E or on the path of the desired air A supplied to the engine E, (A). In addition, the heat absorbing portion 110 may absorb the heat of the engine E itself and the engine oil. The heat absorber 110 has a structure similar to that of a general heat exchanger, and a heat medium L1 for absorbing heat flows.

The heat absorber 110 in this embodiment absorbs the heat of the desired air A supplied to the engine E through the heating medium L1 after passing through the turbocharger T. [

The cooling unit 120 cools the wastes heat-exchanged in the heat absorption unit 110 to a limited temperature for supplying the engine E to the engine E.

That is, in the present invention, the heat absorbing portion 110 and the cooling portion 120 are provided on the moving path of the desired air A flowing into the engine E to multi-stage the desired air A.

The first supply line 200 has a heat medium L1 flowing therein and connects the heat absorbing unit 110 and the first heat exchanger 310 of the waste heat recovery unit 300 to be described later. Accordingly, the heat medium absorbing heat through the heat exchange with the desired air A in the heat absorber 110 flows to the first heat exchanger 310 along the first supply line 200.

The waste heat recovery unit 300 is a device that can absorb heat transferred by the heat medium L1 and utilize it in various places. In this embodiment, the waste heat recovery unit 300 is configured to generate power by driving a separate turbine 330.

The waste heat recovery unit 300 may be formed in accordance with various types of heat exchange cycles, and in this embodiment, it is equipped with an ORC (Organic Rankine Cycle).

The waste heat recovery unit 300 includes a circulation loop 350, a turbine 330, a first heat exchanger 310 pump 340, and a second heat exchanger 320. The circulating loop 350 circulates the circulating fluid L2 in the order of the first heat exchanger 310, the turbine 330, the second heat exchanger 320, and the pump 340, Supply.

The first heat exchanger 310 is disposed on the path of the first supply line 200 to allow the heat medium L1 absorbing heat from the heat absorber 110 to exchange heat with the circulating fluid L2.

The circulating fluid L2 is vaporized through heat exchange with the heating medium L1 via the first heat exchanger 310 along the circulation loop 350 and the vaporized circulating fluid L2 drives the turbine 330 . The circulating fluid L2 via the turbine 330 is again cooled via the second heat exchanger 320 and liquefied. The liquefied circulating fluid L2 is provided to the first heat exchanger 310 through the pump 340.

The circulating fluid L2 flowing in the circulating loop 350 is selected according to the temperature of the heating medium L1 provided in the first heat exchanger 310 and generally a fluid having a boiling point lower than that of water may be used .

The second supply line 400 flows in the heating medium L1 and connects the first heat exchanger 310 of the waste heat recovery unit 300 and the heat absorption unit 110. Therefore, the heat medium L1 that has been discharged from the first heat exchanger 310 to the circulating fluid L2 flows along the second supply line 400 to the heat absorber 110. [

The bypass line 500 is configured such that both ends thereof are respectively connected to the first supply line 200 and the second supply line 400 to selectively bypass the heating medium L1. Specifically, by selectively bypassing the heating medium L1 which is configured to branch at the first supply line 200 and move along the first supply line 200, the heating medium L1 does not flow through the second heat exchanger 320 To the second supply line (400) and again to the heat absorber (110).

A separate flow control valve 510 is provided at a position where the first supply line 200 and the bypass line 500 are connected to each other to control the flow path and flow rate of the heating medium L1 moving along the first supply line 200 And can be selectively adjusted.

The cooler 600 is configured to recover the heat absorbed by the heat absorbing portion 110 by the heating medium L1 flowing into the bypass line 500. The cooler 600 in this embodiment is arranged on the bypass line 500 And is configured to cool the heating medium L1 moving along the bypass line 500 by performing heat exchange with fresh water W. [

The waste heat recovering apparatus according to the present invention is provided with the bypass line 500 and the cooler 600 so that the heat absorbed by the heat medium L1 can be absorbed even if the heat medium L1 does not pass through the waste heat recovering unit 300 So that it can be supplied again to the heat absorbing part 110 again.

The fresh water line 700 flows in the fresh water W provided inside the ship and supplies clean water W to the cooling unit 120, the cooler 600 and the second heat exchanger 320. Specifically, in this embodiment, the fresh water W supplied from the fresh water supply source is divided so that the cooling unit 120, the cooler 600, and the second heat exchanger 320 are independently circulated while circulating the scavenging air A, (L1) and the circulating fluid (L2).

However, the present invention is not limited to this embodiment, and the fresh water line 700 may be connected to the cooling unit 120, the cooler 600, and the second heat exchanger 320 in various ways in parallel and in parallel.

On the other hand, the fresh water line 700 is configured to pass through the cooling unit 120, the cooler 600 and the second heat exchanger 320, by using the fresh water (W) provided in the vessel to the small air ( A), the heating medium (L1) and the circulating fluid (L2) can be cooled to make the configuration of the piping more convenient, each having a separate valve (not shown) fresh water moving along the fresh water line (700) ( It may also be configured to be able to adjust the transit route of W).

The fresh water line 700 may be connected to the cooler 600 and the second heat exchanger 320 continuously so that the fresh water W is sequentially passed through the fresh water line 700, although not shown in the drawing.

As described above, the waste heat recovering apparatus according to the first embodiment of the present invention absorbs the heat generated from the engine E in the heat absorber 110 through the heat medium L1, 1 heat exchanger 310. The first heat exchanger 310 supplies the transferred heat to the circulating fluid L2 to drive the turbine 330. [

However, when the waste heat recovery unit 300 is broken or malfunctioned in this configuration, since the waste heat recovery unit 300 can not operate, the bypass line 500 is separately provided, The cooler 600 is arranged to pass through the bypass line 500 without passing through the heat exchanger 320 so that the scavenging air A is continuously cooled and the waste heat recovery unit 300 can be repaired.

In particular, when the waste heat recovery unit 300 does not operate, fresh water W does not need to pass through the second heat exchanger 320, so that clean water W is supplied to the cooling unit 120 and the cooler (600).

In addition, the fresh water line 700 can independently supply the fresh water W to the cooling unit 120, the cooler 600, and the second heat exchanger 320, .

The cooler 600 and the second heat exchanger 320 are controlled by controlling the flow path of fresh water W to regulate the flow rate of fresh water W through the cooler 600 and the second heat exchanger 320, The temperature of the fresh water W may be adjusted to suit the temperature condition for the heat exchange of the fresh water W.

Meanwhile, in the waste heat recovering apparatus according to the first embodiment of the present invention, the second supply line 400 may further include a temperature sensor 800 for measuring the temperature of the heating medium L1.

The temperature sensor 800 is configured to measure the temperature of the heating medium L1 via the waste heat recovery unit 300 on the second supply line 400 and controls the flow rate control valve 510 according to the measured temperature of the heating medium L1. The flow rate of the heat medium L1 via the waste heat recovery unit 300 and the cooler 600 can be adjusted. The heat medium L1 controls the flow rate of the heat medium L1 through the cooler 600 and the waste heat recovery unit 300 to actively regulate the temperature of the heat medium L1 supplied to the heat absorbing unit 110. [

1 and 3, a state in which the heating medium L1 and the fresh water W are moved is shown in FIG. 1 in which the heating medium L1 is heated in a state where the waste heat recovery unit 300 is normally operated, And then transferred to the waste heat recovery unit 300 along the first supply line 200 after passing through the absorption unit 110. The heat medium L1 moved to the waste heat recovery unit 300 is heat-exchanged with the circulating fluid L2 in the first heat exchanger 310 to be lowered in temperature, and then transferred to the heat absorber 110 again.

Fresh water (W) flowing along the fresh water line (700) circulates through the cooling unit (120) and the second heat exchanger (320) and each independently cools the small air (A) and the circulating fluid (L2).

In this way, the fresh water line 700 continuously cools the scavenging air A, and at the same time, when the waste heat recovery unit 300 operates, it is supplied to the second heat exchanger 320 to cool the circulating fluid L2.

Here, when the heating medium L1 moves along the first supply line 200 to the waste heat recovery unit 300, a part of the heating medium L1 flows through the bypass line 500 through the adjustment of the flow control valve 510 And then supplied to the heat absorbing part 110 again.

The flow rate of the heating medium L1 supplied to the waste heat recovery unit 300 can be adjusted. The temperature of the heating medium L1 discharged after the heat exchange in the waste heat recovery unit 300 is monitored by the temperature sensor 800 described above to adjust the most effective amount of the heating medium L1 to flow to the waste heat recovery unit 300 .

Further, a part of the heating medium L1 passing through the bypass line 500 is cooled by the cooler 600. [ Therefore, even if a part of the heating medium L1 does not pass through the heat supply unit 300, sufficient cooling can be performed.

The temperature of the heating medium L1 supplied to the heat absorber 110 can be adjusted according to the diversification of the cooling path of the heating medium L1 and it is possible to control the amount of fresh water W flowing in the cooler 600 It is also possible to do so.

3, when the waste heat recovery unit 300 is not operated, the heating medium L1 passes through the heat absorbing unit 110 and then flows along the bypass line 500 to the second supply line 400, .

Here, the heating medium L1 is cooled via the cooler 600 disposed on the bypass line 500, and then supplied to the heat absorber 110 along the second supply line 400 again.

The fresh water W flowing along the fresh water line 700 independently cools the purged air A and the heating medium L1 via the cooling part 120 and the cooler 600.

Accordingly, even if the waste heat recovery unit 300 does not operate, the heating medium L1 continuously circulates via the cooler 600 and can cool the air A to be supplied to the engine E. [

Although not shown in the drawing, a plurality of heat absorbing parts 110 may be provided depending on the capacity of the engine E or the like.

Unlike the above-described configuration, the heat absorber 110 can be disposed on the moving path of the exhaust gas G discharged from the engine E without being disposed on the moving path of the scavenging air A ). The heat absorbing portion 110 is disposed in the exhaust path of the exhaust gas G so that the heat medium L1 absorbs the heat of the exhaust gas G and can transfer the heat to the waste heat recovering unit 300. [

Second Embodiment

The construction of the waste heat recovery apparatus according to the second embodiment of the present invention will be described with reference to FIGS. 5 and 6. FIG.

FIG. 5 shows a schematic configuration of a waste heat recovering apparatus according to a second embodiment of the present invention. FIG. 6 shows a schematic view of a waste heat recovering apparatus of FIG. 5, in which a heat medium L1 absorbing heat in the heat absorber 110 is bypassed And moves along the line 500. As shown in Fig.

As shown in the drawing, the basic configuration is similar to the configuration of the first embodiment described above, but the heat absorbing portion 110 is a modified configuration.

The heat absorbing portion 110 not only absorbs the heat of the purged air A supplied to the engine E as in the first embodiment but also absorbs the heat of the exhaust gas G discharged from the engine E separately So that it can be absorbed.

The heat absorber 110 includes a first heat absorber 112 and a second heat absorber 114.

The first heat absorber 112 allows the heat medium L1 to absorb heat generated by heat exchange with the air A to be supplied to the engine E in a high pressure state.

The second heat absorber 114 allows the heat medium L1 to absorb heat generated by heat exchange with the exhaust gas G generated from the engine E. [

That is, the first heat absorber 112 and the second heat absorber 114 are disposed on the moving path of the scavenging air A and the exhaust gas G, respectively, to heat-exchange the heat medium L1 with the heat medium L1, So that heat generated from the engine E can be absorbed.

Accordingly, the first supply line 200 is divided and connected to the first heat absorber 112 and the second heat absorber 114 as shown, and the flowing heat medium L1 is divided into the first heat absorber 112) and the second heat absorber (114).

The heat absorbed in the heating medium L1 moves to the waste heat recovery unit 300 along the first supply line 200 as shown in FIG. In the waste heat recovery unit 300, the heat medium L1 transfers heat absorbed by the heat exchange with the circulating fluid L2, and then is transferred to the heat absorption unit 110 again.

6, when the waste heat recovery unit 300 does not operate, the heating medium L1 passes through the cooler 600 along the bypass line 500 and does not pass through the waste heat recovery unit 300 And the fresh water W are configured to cool through the fresh water line 700 through only the cooling unit 120 and the cooler 600 by exchanging heat with the desired air A and the heating medium L1.

5 and 6, the first heat absorber 114 and the second heat absorber 115 are arranged in parallel with respect to the waste heat recovering unit 300. Alternatively, the first heat absorber 114 and the second heat absorber 115 may be arranged in parallel, The heat absorber 115 is arranged in series with respect to the waste heat recovery unit 300 so that the heat medium L1 flowing through the waste heat recovery unit 300 is discharged to the first heat absorber 114 and the second heat absorber 115 sequentially As shown in FIG.

My 3 Example

Next, the structure of the ship heat recovery system according to the third embodiment of the present invention will be described with reference to FIGS. 7 and 8. FIG.

FIG. 7 is a schematic view showing the construction of a waste heat recovery apparatus according to the third embodiment of the present invention. FIG. 8 is a schematic view of the waste heat recovering apparatus of FIG. 7, in which the heating medium L1 is divided into bypass lines 500 and cooling lines 900 Therefore, FIG.

Referring to the drawing, the basic configuration has a configuration similar to that of the first embodiment described above, but further includes a separate cooling line 900 in which the heating medium L1 flowing along the second supply line 400 is bypassed And the cooler 600 is provided on the cooling line 900 rather than the bypass line 500. [ Other configurations are the same as those of the above-described embodiment, and the description thereof will be omitted.

As shown, the cooling line 900 is branched and disposed on the second supply line 400 and is selectively disposed on the path of the heat medium L1 traveling through the waste heat recovery unit 300 or the bypass line 500 Cooler (600).

That is, a separate auxiliary valve 910 is further provided on the second supply line 400 to regulate the flow rate of the heating medium L1 via the cooler 600.

The heating medium L1 having the increased temperature via the heat absorber 110 flows into the first supply line 200 through the heat absorber 110. In this case, To the waste heat recovery unit (300).

The heating medium L1 which has moved to the waste heat recovery unit 300 and cooled by the circulating fluid L2 flows along the second supply line 400 to the heat absorption unit 110. [

8, when the waste heat recovery unit 300 malfunctions or fails, the heating medium L1 moving along the first supply line 200 is bypassed by the bypass control line 510 And does not pass through the waste heat recovery unit 300. [

The heating medium L1 moved along the bypass line 500 moves along the cooling line 900 and is cooled through the cooler 600. [

Accordingly, the heat medium L1 is discharged through the cooler 600 and absorbed by the heat absorber 110, and is then supplied to the heat absorber 110 to absorb heat.

That is, in this embodiment, the cooler 600 is provided at the rear end of the waste heat recovery unit 300 and at the front end of the heat absorption unit 110 to discharge heat from the waste heat recovery unit 300 during a malfunction of the waste heat recovery unit 300 It is possible to prevent the heat medium L1 from flowing directly into the heat absorbing portion 110. [

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. . Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: Heat absorption unit 110: Heat absorption unit
120: cooling unit 200: first supply line
300: waste heat recovery unit 400: second supply unit
500: bypass line 510: flow control valve
600: Cooler 700: Fresh water line
800: Temperature sensor 900: Cooling line
910: Auxiliary valve G: Exhaust gas
A: Desired air L1: Heat medium
L2: circulating fluid W: fresh water

Claims (7)

A heat absorbing unit including a heat absorbing unit for recovering heat generated by driving of the engine and a cooling unit for cooling heat generated by driving the engine;
A first supply line through which the heat medium exchanged in the heat absorber flows;
A waste heat recovery unit including a first heat exchanger communicating with the first supply line and absorbing heat recovered by the heat medium;
A second supply line configured to transfer the heat medium heat-exchanged in the first heat exchanger to the heat absorption unit;
A bypass line having opposite ends connected to the first supply line and the second supply line, respectively, to selectively bypass the heating medium;
A cooler for recovering the heat absorbed by the heat absorbing portion of the heat medium flowing into the bypass line; And
And a fresh water line for circulating the fresh water to at least one of the cooling unit, the cooler, and the waste heat recovering unit. The method of claim 1,
The cooler
A waste heat recovery device for ship which is disposed on the bypass line and cools the heat medium moving along the bypass line by performing heat exchange with the clean water, The method of claim 1,
And a cooling line branched on the second supply line to selectively bypass the heat medium, and provided with a cooler to cool the heat medium by exchanging heat with the fresh water. The method of claim 1,
The second supply line is provided with a temperature sensor for measuring the temperature of the heating medium,
Further comprising a flow control valve between the first supply line and the bypass line for selectively flowing the heat medium according to a measured value of the temperature sensor. The method of claim 1,
Wherein the waste heat recovery unit includes a second heat exchanger for cooling the circulating fluid absorbing heat in the first heat exchanger,
Wherein the fresh water line branches in the moving path of the fresh water and supplies a part of the fresh water to the second heat exchanger to cool the circulating fluid. The method of claim 1,
Wherein the waste heat recovery unit includes a second heat exchanger for cooling the circulating fluid absorbing heat in the first heat exchanger,
And the fresh water line is connected to the second heat exchanger so that the fresh water passing through the cooler continuously moves to cool the circulating fluid in the second heat exchanger. The method of claim 1,
The fresh water line,
And to circulate the fresh water independently to each of the cooling section and the cooler.

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