JP7048090B2 - Water production equipment - Google Patents

Description

The present invention relates to a water production apparatus used for producing fresh water from seawater.

For ships operating on the sea, steam from the boiler mounted on the ship or waste heat of cooling water from the diesel engine is used as a heat source to evaporate the seawater pumped from the sea under high vacuum and then condense it. By doing so, desalination has been conventionally performed. As a water production device of this type, for example, the one described in Patent Document 1 has been proposed.

As shown in FIG. 10, the water making apparatus 100 described in Patent Document 1 includes a heater 101 that heats and evaporates the supplied raw material seawater, and a condenser 102 that condenses the steam generated by the heater 101. I have. A plurality of heat transfer tubes for heating are provided in the heater 101, and heat transfer for heating is performed by heat exchange with the cooling water used for cooling the diesel engine supplied as a heat source in the heater 101. The raw material seawater flowing in the pipe is heated and evaporated, and steam is supplied to the condenser 102. A plurality of heat transfer tubes for condensation are provided in the condenser 102, and the steam supplied in the condenser 102 is cooled and condensed by heat exchange with the cooling seawater flowing in the heat transfer tubes for condensation. It becomes condensed water and is discharged from the condenser 102. A part of the cooling seawater that has passed through the heat transfer tube for condensation and is heated is supplied to a plurality of preheat transfer tubes provided in the condenser 102 and heated by the steam in the condenser 102. , The raw material seawater is supplied to the heater 101, and the balance is discharged to the outside of the ship or the like.

In the water making apparatus 100 having the above configuration, the condenser 102 and the heater 101 are connected and fixed by tightening bolts and nuts, and the pedestal 103 including a plurality of legs 104 attached to the outer peripheral surface of the condenser 102 is used. The condenser 102 and the heater 101 are supported above the floor surface.

Japanese Unexamined Patent Publication No. 6-254534

Since the gantry 103 has a structure in which the gantry 103 is integrated with the condenser 102, the water brewing device 100 having the above configuration cannot be stored in a container due to the size of its overall shape in a form having a large capacity. There is a problem that the cost becomes high when transporting 100. Further, when replacing the existing water-making device 100 installed on the ship, if the carry-in route in the ship is narrow, there is a problem that the water-making device 100 cannot be transported. Further, when replacing only the condenser 102 of the existing water making apparatus 100, it is necessary to transport and replace the condenser 102 together with the gantry 103. Therefore, if the carry-in route in the ship is narrow, the condenser 102 is used. There is a problem that it cannot be transported.

The present invention has been made by paying attention to the above-mentioned problems, and an object of the present invention is to provide a water production device that can be easily stored in a container and can be easily transported even in a narrow carry-in route in a ship. And.

The water-making device according to the present invention includes a heater that heats a liquid to be treated to generate steam, a condenser that is detachably connected on the heater and condenses the steam generated by the heater, and a condenser. A pedestal that is installed on the installation surface and supports the condenser from below, the pedestal has a plurality of stanchions, and the condenser is connected to the upper end of each stanchion of the pedestal. It is characterized by having a part.

In the water-making device having the above configuration, the condenser has a plurality of legs, the plurality of legs have the connection portion with the support column corresponding to the lower end, and the lower end thereof is the condenser. It is preferable that it protrudes below the connection portion with the heater.

Further, in the water making apparatus having the above configuration, it is preferable that the heater is detachably attached to at least one of the columns of the gantry.

According to the water-making apparatus according to the present invention, the condenser can be separated from the gantry, and each unit such as the condenser, the heater, and the gantry can be separated and easily stored in the container. Therefore, it can be easily transported even in a narrow carry-in route in the ship.

It is a front view of a water making apparatus. It is a rear view of a water making apparatus. It is a vertical sectional view of the condenser and the heater in the water making apparatus of FIG. It is a front view of a heater. It is a front view of a condenser. It is a front view of the state where the heater is attached to the gantry. It is a left side view of a state where a heater is attached to a gantry. It is a vertical cross-sectional view which shows the connection part of this embodiment in an enlarged manner. It is a vertical sectional view which shows the connection part of another embodiment in an enlarged manner. It is a front view of the conventional water making apparatus.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. 1 and 2 show the external configuration of the water production device 1 of the present embodiment, and FIG. 3 shows the internal configuration of the heater 2 and the condenser 3 in the water production device 1 of the present embodiment, respectively. Further, FIG. 4 shows the appearance configuration of the heater 2, FIG. 5 shows the appearance configuration of the condenser 3, and FIGS. 6 and 7 show the appearance configuration of the heater 2 attached to the gantry 4, respectively. Shows.

The water-making device 1 of the present embodiment condenses a heater 2 that heats a liquid to be treated such as seawater to generate steam, and a steam that is detachably mounted on the heater 2 and generated by the heater 2. It is provided with at least a condenser 3 to be installed and a pedestal 4 installed on an installation surface such as a floor surface to support the condenser 3 from below.

The heater 2 includes a cylindrical main body portion 20 and a tray-shaped raw water introduction portion 30, and the raw water introduction portion 30 is connected and fixed to the lower end portion of the main body portion 20 by tightening bolts and nuts. ..

The main body 20 is divided into the first heating chamber 24A and the second heating chamber 24B by covering the lower opening and the upper opening with the bottom plate 21 and the lid plate 22, respectively, and partitioning the inside by the partition plate 23 extending vertically. It is divided. A plurality of heat transfer tubes 25 extending vertically are housed in the first heating chamber 24A and the second heating chamber 24B in the main body 20, and each heat transfer tube 25 has a bottom plate 21 and a lid plate 22 at both ends. It is fixed to the bottom plate 21 and the lid plate 22 by being inserted into the corresponding insertion hole among the plurality of insertion holes formed in each.

On the side wall of the main body 20, a first supply port 26A for supplying hot water such as jacket cooling water used for cooling a diesel engine as a heating fluid is provided corresponding to the first heating chamber 24A. .. The heating fluid supplied from the first supply port 26A passes around each heat transfer tube 25 in the first heating chamber 24A, and is provided above the first supply port 26A on the side wall of the main body 20. 1 It is discharged from the discharge port 27A. Further, on the side wall of the main body 20, for example, a second supply port 26B for supplying steam as a heating fluid is provided corresponding to the second heating chamber 24B. The heating fluid supplied from the second supply port 26B passes around each heat transfer tube 25 in the second heating chamber 24B, and is provided below the second supply port 26B on the side wall of the main body 20. 2 It is discharged from the discharge port 27B. A plurality of baffle plates 28 for meandering the flow path of the heating fluid are provided in the first heating chamber 24A and the second heating chamber 24B, respectively.

The raw water introduction section 30 is divided into a first introduction chamber 32A and a second introduction chamber 32B corresponding to the first heating chamber 24A and the second heating chamber 24B, respectively, by partitioning the inside by a partition plate 31 extending vertically. Has been done. The first introduction chamber 32A and the second introduction chamber 32B communicate with the lower end of the heat transfer tube 25 in the first heating chamber 24A and the second heating chamber 24B, respectively. On the side wall of the raw water introduction portion 30, introduction ports 33A and 33B for introducing the liquid to be treated are formed corresponding to the first introduction chamber 32A and the second introduction chamber 32B, respectively. The liquid to be treated introduced into the raw water introduction section 30 from the introduction ports 33A and 33B is supplied to each heat transfer tube 25, and is supplied by the heating fluid around each heat transfer tube 25 while rising in each heat transfer tube 25. It is heated and evaporated, becomes steam, and is supplied to the condenser 3.

The condenser 3 includes a cylindrical casing 40 having a diameter larger than that of the main body 20 of the heater 2. The casing 40 and the main body 20 of the heater 2 are connected and fixed by tightening bolts and nuts with the lid plate 22 sandwiched between them, and the heater 2 is supported by the condenser 3 in a suspended state. There is. The steam supplied from the heater 2 is introduced into the inside of the casing 40 from the lower opening of the casing 40 and rises inside the casing 40. The inside of the casing 40 is partitioned into a first air-water separation chamber 42A and a second air-water separation chamber 42B by a partition wall 41 composed of a lower partition wall 41A and an upper partition wall 41B and a receiving member 47. Each of the air-water separation chambers 42A and 42B is provided with the air-water separation means 43 for capturing droplets of the liquid to be treated from the steam. The steam separating means 43 is, for example, a steam separating plate 430 and a demista (a mesh separator in which a plurality of fine mesh formed by fine threads are laminated) 431 arranged above the steam separating plate 430. Consists of.

A gas discharge port 44A for discharging gas such as steam is formed on the upper portion of the side wall of the casing 40 corresponding to the first air-water separation chamber 42A, and the side wall of the receiving member 47 protruding from the casing 40 is formed. A gas discharge port 44B for discharging a gas such as steam is formed corresponding to the second air-water separation chamber 42B. Further, at the lower part of the side wall of the casing 40, there are liquid discharge ports 45A and 45B corresponding to the first steam separation chamber 42A and the second steam separation chamber 42B, respectively, to discharge the liquid to be treated separated from the steam. It is formed.

One end of the steam supply pipe 5 is connected to the gas discharge port 44A on the first air / water separation chamber 42A side of the casing 40, and the other end of the steam supply pipe 5 is the main body 20 of the heater 2. It is connected to the second supply port 26B on the second heating chamber 24B side. The steam generated in the first heating chamber 24A of the heater 2 is supplied to the first air-water separation chamber 42A of the condenser 3, and then a part of the steam is passed through the steam supply pipe 5 to the second heating chamber of the heater 2. It is supplied to 24B as a heating fluid. The steam supplied as a heating fluid to the second heating chamber 24B of the heater 2 is condensed in the second heating chamber 24B by being cooled by the liquid to be treated in each heat transfer tube 25. The fresh water produced by the condensation is collected from the second discharge port 27B by the second fresh water recovery pipe 12.

The steam supply pipe 5 orbits around the condenser 3 from the first air / water separation chamber 42A side (rear side) of the condenser 3 (casing 40) to the right side, and is located sideways on the right side of the heater 2. After inclining downward, it curves toward the right side surface of the heater 2 and extends horizontally, so that the gas discharge port 44A on the first steam separation chamber 42A side of the condenser 3 and the second heater 2 2 It is connected to the second supply port 26B on the heating chamber 24B side. In the present embodiment, the steam supply pipe 5 is composed of a condenser side pipe 5A connected to the gas discharge port 44A of the condenser 3 and a heater side pipe 5B connected to the second supply port 26B of the heater 2. It is configured and the condenser side pipe 5A and the heater side pipe 5B are connected to each other.

Further, one end of the bleeding pipe 6 is connected to the gas discharge port 44B on the second air / water separation chamber 42B side of the casing 40, and the other end of the bleeding pipe 6 is connected to, for example, a water ejector 7. There is. In the present embodiment, the gas in the second gas-liquid separation chamber 42B is sucked by the water ejector 7, and the inside of the second gas-liquid separation chamber 42B is maintained in a reduced pressure (vacuum) state lower than the atmospheric pressure.

One end of the first raw water supply pipe 8 is connected to the liquid discharge port 45A on the first air / water separation chamber 42A side of the casing 40, and the other end of the first raw water supply pipe 8 is the heater 2. It is connected to the second introduction port 33B on the second introduction room 32B side of the raw water introduction unit 30. The liquid to be treated separated from the steam in the first air-water separation chamber 42A of the condenser 3 is supplied as raw water to the second introduction chamber 32B of the heater 2 via the first raw water supply pipe 8. Further, one end of the brine discharge pipe 9 is connected to the liquid discharge port 45B on the second air / water separation chamber 42B side of the casing 40, and the other end of the brine discharge pipe 9 is a water ejector in the present embodiment. It is connected to 7. The liquid to be treated (brine) separated from the steam in the second air-water separation chamber 42B of the condenser 3 is sucked by the water ejector 7 and then discharged to the outside of the ship.

The condenser 3 further includes a plurality of heat transfer tubes 46 provided inside the casing 40. The plurality of heat transfer tubes 46 are housed in a cylindrical receiving member 47 horizontally provided so as to penetrate the casing 40, and the upper portion of the receiving member 47 receives steam inside the casing 40. It has a tub shape that is open for introduction into the member 47. A first header 48A and a second header 48B are connected to both ends of the receiving member 47, respectively.

In the present embodiment, the plurality of heat transfer tubes 46 are arranged on one side (second gas-liquid separation chamber 43B side) of the upper partition wall 42B, and both ends of each heat transfer tube 46 are on the left wall surface and the right side of the receiving member 47. It is fixed to the wall surface and communicates with the inside of both the first and second headers 48A and 48B. A part of the plurality of heat transfer tubes 46 constitutes a condenser, and the rest constitutes a preheater. In FIG. 3, each heat transfer tube 46 surrounded by a broken rectangular frame is a heat transfer tube constituting the preheater.

The first header 48A is provided with a cooling water inlet 49 for introducing a liquid to be treated such as seawater as cooling water. In the present embodiment, the water ejector 7 is connected to the cooling water inlet 49, and seawater from an ejector pump (not shown) is introduced as cooling water. The first header 48A is divided into two upper and lower header chambers (not shown) by a partition plate (not shown), and constitutes a condenser among a plurality of heat transfer tubes 46 through the lower header chamber. The liquid to be treated is supplied to a part of the heat transfer tubes 46. The liquid to be treated supplied to each heat transfer tube 46 constituting the condenser flows in each heat transfer tube 46 toward the second header 48B, and at this time, flows into the second steam separation chamber 42B of the condenser 3. The supplied steam is condensed by being cooled by the liquid to be treated in each heat transfer tube 46. The fresh water generated by the condensation is collected by the first fresh water recovery pipe 10 from the first fresh water outlet 50 provided in the receiving member 47.

The second header 48B is divided into two upper and lower header chambers (not shown) by a partition plate (not shown), and the liquid to be treated supplied to the header chamber below the second header 48B is a part. Is discharged from the cooling water outlet 51 provided in the lower header chamber, and a part of the water is supplied to the upper header chamber and is supplied to a part of the heat transfer tubes 46 constituting the preheater among the plurality of heat transfer tubes 46. The header. The liquid to be treated supplied to each heat transfer tube 46 constituting the preheater flows toward the header chamber above the first header 48A, and at this time, is supplied to the second steam separation chamber 42B of the condenser 3. It is heated by the steam. The steam used for heating the liquid to be treated condenses into fresh water, which is recovered from the first fresh water outlet 50 provided in the receiving member 47 by the first fresh water recovery pipe 10.

The preheated liquid to be treated supplied to the first header 48A is discharged from the raw water discharge port 52 provided in the first header 48A. One end of the second raw water supply pipe 11 is connected to the raw water discharge port 52, and the other end of the second raw water supply pipe 11 is the first on the first introduction chamber 32A side of the raw water introduction portion 30 of the heater 2. It is connected to the introduction port 33A. The preheated liquid to be treated discharged from the first header 48A is supplied as raw water to the first introduction chamber 32A of the heater 2 via the second raw water supply pipe 11.

The heater 2 and the condenser 3 are supported above the installation surface by the gantry 4. The gantry 4 has a plurality of support columns 60, and the heater 2 is housed in the center of the space between the plurality of support columns 60. In the present embodiment, each strut portion 60 is formed in an L-shape in cross-sectional view, and is connected to the adjacent strut portion 60 by a connecting portion 61 at the lower end portion. The upper and lower ends of the support columns 60 are aligned at the same height, and the upper ends and the lower ends of the support columns 60 are located on the same horizontal plane. Each strut portion 60 has a flat plate-shaped base portion 62 at the lower end, and each strut portion 60 is stably erected on the installation surface by the base portion 62. The shape of the support column 60 is not limited to the L-shape in cross-sectional view, and may be U-shaped or H-shaped in cross-sectional view.

The condenser 3 is integrally attached to the outer peripheral surface of the casing 40 and has a plurality of legs 34 that correspond one-to-one with the plurality of support columns 60 of the gantry 4. In the present embodiment, each leg portion 34 is formed in an L-shape in cross-sectional view, and the lower end thereof protrudes below the connection portion (lower end of the casing 40) of the condenser 3 with the heater 2. When the lower end of the leg portion 34 touches the installation surface, the connection portion (lower end of the casing 40) of the condenser 3 with the heater 2 is located above the installation surface. The lower ends of the legs 34 are aligned at the same height, and the lower ends of the legs 34 are located on the same horizontal plane. The shape of the leg portion 34 is not limited to the L-shape in cross-sectional view, and may be U-shaped or H-shaped in cross-sectional view.

A connecting portion 63 for connecting the corresponding strut portion 60 and the leg portion 34 is provided between each strut portion 60 and each leg portion 34. As shown in FIG. 8, for example, the connection portion 63 is a first connection plate 64 provided at the lower end of each leg portion 34 of the condenser 3, and a second connection provided at the upper end of each support column portion 60 of the gantry 4. It has a plate 65 and a bolt 66 and a nut 67 for connecting the connecting plates 64 and 65. Insertion holes for bolts 66 are formed in the connection plates 64 and 65. Condensation by superimposing the first connection plate 64 at the lower end of each leg 34 on the second connection plate 65 at the upper end of each corresponding column 60 of the gantry 4 on a one-to-one basis and fastening them with bolts 66 and nuts 67. The vessel 3 is stably installed on the gantry 4.

In the present embodiment, the gantry 4 has a heater 2 detachably attached to at least one support column 60. The lower end of each support column 60 of the gantry 4 is located below the lower end of the heater 2 when the heater 2 is attached to the support column 60, and the lower end of each support column 60 is in contact with the installation surface. The heater 2 is located above the installation surface. Further, the upper end of each support column 60 of the gantry 4 is located below the upper end of the heater 2 when the heater 2 is attached to the support column 60, and the condenser 3 is installed on the gantry 4. At that time, the height position is set so that the lower end of the condenser 3 and the upper end of the heater 2 are in contact with each other, whereby the condenser 3 and the heater 2 can be connected by bolts and nuts. Will be.

In the present embodiment, the gantry 4 has a loading / unloading means interposed between at least one support column 60 and the heater 2, and the two support columns 60 support the heater 2 by the loading / unloading means. The heater 2 can be carried in and out from between the inside and outside of the gantry 4.

In the present embodiment, the carry-in / out means is configured by a hinge mechanism 13 that rotates the heater 2 around a predetermined support column 60. The hinge mechanism 13 has a round bar-shaped rotating shaft 130 rotatably supported by a pair of upper and lower bearings 131 integrally attached to a predetermined support column 60, and a flat plate shape integrally attached to the rotating shaft 130. The support member 132 is composed of a flat plate-shaped fixing member 133 integrally attached to the outer peripheral surface of the heater 2.

A plurality of bolt holes 135 are formed on the plate surface of the fixing member 133 at predetermined intervals in the vertical direction. On the other hand, on the plate surface of the support member 132, a position adjusting hole 134 formed of an elongated hole extending in the vertical direction is formed according to the bolt hole 135 of the fixing member 133. The support member 132 and the fixing member 133 are brought into surface contact with the position adjusting hole 134 and the bolt hole 135 overlapping each other, and the bolt 136 is inserted into the position adjusting hole 134 and the bolt hole 135 and tightened with the nut 137. The fixing member 133 is fixed to the support member 132, and the heater 2 can rotate about the rotation shaft 130 with respect to the predetermined support column portion 60. By this rotation, the heater 2 can be carried out from the space inside the gantry 4 to the space outside the gantry 4 through between the two support columns 60, and conversely, from the space outside the gantry 4 to the space inside the gantry 4. Can be carried in.

As the hinge mechanism 13, the one disclosed in Japanese Patent No. 6099497 can be used. Further, the loading / unloading means is not limited to the hinge mechanism 13, but the loading / unloading means such as the slide mechanism disclosed in Japanese Patent No. 6099497, and the two support columns 60 while supporting the heater 2. If the heater 2 can be carried in and out from between the inside and outside of the gantry 4, other carrying-in / out means can be used.

In the water making apparatus 1 of the present embodiment having the above-described configuration, since the condenser 3 is removable from the gantry 4, even if the capacity is large and the condenser cannot be stored in the container as a whole, the condenser 3 can be attached to and detached from the gantry 4. By removing 3 from the gantry 4, the units such as the condenser 3, the heater 2 and the gantry 4 can be separately stored in the container. Therefore, the water making apparatus 1 can be easily transported and the transportation cost can be reduced.

Further, when replacing the existing water production device 1 installed on the ship, even if the carry-in route in the ship is narrow, the water production device 1 can be separately transported for each unit, so that the water production device 1 can be transported. The replacement of 1 can be easily performed. Further, when replacing only the condenser 3 of the existing water making apparatus 1, it is not necessary to transport and replace the condenser 3 together with the gantry 4, and only the condenser 3 needs to be transported and replaced. The condenser 3 can be transported even if the carry-in route in the ship is narrow, and the condenser 3 can be easily replaced.

As described above, according to the water production apparatus 1 of the present embodiment, each unit can be easily stored in a container, and can be easily transported even in a narrow carry-in route in a ship.

In addition, according to the water making apparatus 1 of the present embodiment, since the lower end of each leg portion 34 of the condenser 3 protrudes below the condenser 3, the condenser 3 is mounted on the installation surface by each leg portion 34. Can stand above. In the process of transporting the condenser 3, the condenser 3 may be temporarily placed on an installation surface such as a floor surface, and at that time, each leg 34 is connected to the heater 2 of the condenser 3. By protruding below the portion, the condenser 3 can be placed on the installation surface without the connection portion with the heater 2 coming into contact with the installation surface. This makes it possible to prevent the connection portion with the heater 2 from being deformed, damaged, or soiled due to the weight of the condenser.

In addition, according to the water making apparatus 1 of the present embodiment, since the heater 2 can be attached to the gantry 4, the heater 2 can be stationary above the installation surface by the gantry 4. By floating the heater 2 from the installation surface in this way, the hinge mechanism 13 facilitates loading and unloading. Further, by installing equipment capable of transporting the heater 2 between the heater 2 and the installation surface, the heater 2 can be carried in and out.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

Further, in the above embodiment, the water making apparatus 1 is a double-effect type, but it may be a simple single-effect type having no partition plates 23, 31 or a partition wall 41, or a heater 2 and a condenser. By partitioning 3 with a plurality of partition plates 23, 31 and a partition wall 41, three or more heating chambers and air-water separation chambers are formed, and the steam generated in the heating chamber in the previous stage is used as a heating fluid in the heating chamber in the subsequent stage. By using it, it is possible to make it a triple or more utility type.

Further, in the above embodiment, the heater 2 is rotatably attached to the gantry 4 by a hinge mechanism 13 around a predetermined strut portion 60, but is non-rotatably attached to and detachable from the predetermined strut portion 60 of the gantry 4. It may be attached to the gantry 4 or may not be attached to the gantry 4.

Further, in the above embodiment, the connecting portion 63 may have a structure shown in FIG. 9, for example, and is not limited to a specific structure. The connection portion 63 shown in FIG. 9 includes a first connection plate 64 provided at the lower end of each leg portion 34 of the condenser 3, and a second connection plate 65 provided at the upper end of each support column portion 60 of the gantry 4. It has a positioning pin 68 for aligning the connection plates 64 and 65, a guide plate 69, and a bolt 66 and a nut 67 for connecting the guide plate 69, the leg portion 34, and the strut portion 60. The positioning pin 68 is provided on one of the two connection plates 64 and 65 (second connection plate 65 in the illustrated example), and the positioning pin 68 is provided on the other connection plate (second connection plate 65 in the illustrated example). 68 insertion holes are formed. Further, the insertion holes for the bolts 66 are formed in the legs 34, the columns 60, and the guide plate 69. After superimposing the first connection plate 64 at the lower end of each leg portion 34 on the second connection plate 65 at the upper end of each support column 60 corresponding to the gantry 4 on a one-to-one basis using the positioning pin 68, the guide plate 69 is attached to the leg. The condenser 3 is stably installed on the gantry 4 by arranging the guide plate 69 so as to straddle the portion 34 and the strut portion 60 and fastening the guide plate 69, the leg portion 34 and the strut portion 60 with bolts 66 and nuts 67. To.

The positioning pin 68 preferably has a tapered shape that tapers toward the tip. Since the positioning pin 68 has a tapered shape, it becomes easy to align the two connecting plates 64 and 65 using the positioning pin 68.

1 Water making equipment 2 Heater 3 Condensator 4 Stand 5 Steam supply pipe 23 Partition plate 24A, 24B Heating chamber 60 Strut 63 Connection 64 Leg

Claims (2)

A heater that heats the liquid to be treated to generate steam,
A condenser that is detachably connected on the heater and condenses the steam generated by the heater,
It is equipped with a stand that is installed on the installation surface and supports the condenser from below.
The gantry has a plurality of support columns and has a plurality of support columns.
The condenser has a connection that is connected to the upper end of each strut of the gantry.
The condenser further has a plurality of legs and has a plurality of legs.
The plurality of legs have the connection portion with the corresponding support column portion of the gantry at the lower end, and the lower end portion protrudes below the connection portion of the condenser with the heater. .. The water-making device according to claim 1 , wherein the heater is detachably attached to at least one support column of the gantry.

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