JP2017078374A - Fresh water generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fresh water generation system capable of securing a heat quantity for obtaining a sufficient quantity of plain water even in the case where a temperature of jacket cooling water to be drained from an internal combustion engine falls.SOLUTION: A fresh water generation system 1 comprises: a fresh water generation device 2 including a heater 3; a first cooling water flow passage 7 in which exhaust air cooling water is circulated; a second cooling water flow passage 8 in which jacket cooling water is circulated; a first circulation path 9; and a second circulation path 10. The fresh water generation system is configured to guide cooling water flowing in the first circulation path 9 or cooling water flowing in the second circulation path 10 to the heater 3 and to exchange heat with seawater. In the circulation path 9 where the cooling water to be guided to the heater 3 flows, at an upstream side of the heater 3, a heat exchanger 16 is provided for exchanging heat between the cooling water flowing in the circulation path 9 and the cooling water flowing in the other circulation path 10. In the other circulation path 10, at an upstream side of the heat exchanger 16, a flow regulating valve 23 is provided for regulating a flow rate of the cooling water to be guided to the heat exchanger 16.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a desalination system for producing fresh water from seawater, and more particularly to a desalination system using waste heat in an internal combustion engine such as a diesel engine.

  In general, ships operating on the sea use fresh heat from diesel engines mounted on ships as a heat source to produce fresh water by evaporating seawater pumped from the sea under high vacuum. Yes. For example, in the fresh water generator described in Patent Document 1, the jacket cooling water used for cooling the diesel engine is guided to the fresh water generator, and the water vapor generated by evaporating by heat exchange with seawater is cooled and condensed to produce fresh water. It has become. Further, exhaust gas discharged from the diesel engine is also used for the amount of heat for desalination of seawater.

JP-A 52-27916

  However, as the efficiency of diesel engines increases in recent years, the temperature of the jacket cooling water decreases due to a decrease in the main engine load (output) of the diesel engine (decrease in waste heat). Will fall. As a result, there is a problem that a sufficient amount of fresh water cannot be obtained. Moreover, since the amount of waste heat due to exhaust gas from the diesel engine is also decreasing, it is necessary to secure the amount of heat to obtain a sufficient amount of fresh water.

  The present invention has been made paying attention to the above-described problem, and is for obtaining a sufficient amount of fresh water even when the temperature of jacket cooling water discharged from an internal combustion engine (diesel engine) decreases. An object of the present invention is to provide a fresh water generation system capable of securing a calorific value.

  An object of the present invention is to provide a fresh water generator having a heater for heating sea water in a fresh water system for producing fresh water from sea water introduced into a ship using waste heat from an internal combustion engine mounted on the ship. A first cooling water passage for circulating cooling water to an air cooler for cooling combustion air supplied from the supercharger to the internal combustion engine; a second cooling water passage for circulating cooling water for cooling the internal combustion engine; A first circulation path that returns to the first cooling path after being diverted from the first cooling water path; a second circulation path that returns to the second cooling path after being diverted from the second cooling water path; The cooling water flowing through the first circulation path or the cooling water flowing through the second circulation path is led to the heater to exchange heat with seawater, and the first circulation path and the first circulation path Of the two circulation paths, cooling water led to the heater flows A heat exchanger for exchanging heat between the cooling water flowing through the circulation path and the cooling water flowing through another circulation path is provided on the upstream side of the heater, and the other circulation path includes the heat exchanger. This is achieved by a fresh water generation system provided with a flow rate adjustment valve for adjusting the flow rate of cooling water led to the heat exchanger on the upstream side of the heat exchange device.

  The fresh water generation system of the first embodiment preferably further includes a central cooler for cooling the cooling water flowing through the first cooling channel and the second cooling channel.

  Moreover, in the fresh water generation system of the said 1st Embodiment, in the circulation path through which the cooling water guide | induced to the said heater flows among the said 1st circulation path and the said 2nd circulation path, it is an upstream of the said heat exchanger. Preferably, a first temperature detector and a second temperature detector are provided on the downstream side, and a third temperature detector is provided on the upstream side of the heat exchange device in the other circulation path.

  The fresh water generation system of the first embodiment further includes a control device connected to the first temperature detector, the second temperature detector, the third temperature detector, and the flow rate adjustment valve, The control device measures the temperature of the cooling water in the other circulation path when the temperature of the cooling water led to the heater is lower than a set temperature, and adjusts the flow rate when the temperature is higher than the set temperature. It is preferable to further include a central cooler for cooling the cooling water flowing through the first cooling flow path and the second cooling water flow path that opens the valve and guides the cooling water to the heat exchanger.

  In the fresh water generation system of the first embodiment, when the temperature of the cooling water led to the heater is higher than a set temperature, the control device measures the temperature of the cooling water in the other circulation path. When the temperature is lower than the set temperature, it is preferable to open the flow rate adjustment valve and guide the cooling water to the heat exchanger.

  In the fresh water generation system of the first embodiment, when the temperature of the cooling water led to the heater is higher than a set temperature, the control device measures the temperature of the cooling water in the other circulation path. When the temperature is higher than the set temperature, it is preferable to control the central cooler to lower the temperature of the cooling water flowing through the first cooling channel and the second cooling channel.

  An object of the present invention is to provide a fresh water production system for producing fresh water from seawater introduced into a ship using waste heat from an internal combustion engine mounted on the ship. A first cooling water passage for circulating cooling water to an air cooler for cooling combustion air supplied to the internal combustion engine; a second cooling water passage for circulating cooling water for cooling the internal combustion engine; and the first cooling water flow A first circulation path returning to the first cooling flow path after branching from the path, and a second circulation path returning to the second cooling flow path after branching from the second cooling water flow path, The cooling water flowing through one circulation path and the cooling water flowing through the second circulation path are guided to the heater to exchange heat with seawater, and the first circulation path has an upstream side of the heater. On the side, the first temperature detector and the flow of cooling water led to the heater A first flow rate adjusting valve for adjusting the flow rate, and a second temperature detector on the second circulation path upstream of the heater and a flow rate for adjusting the flow rate of cooling water led to the heater. It is also achieved by the fresh water generation system of the second embodiment provided with two flow rate regulating valves.

  The fresh water generation system of the second embodiment preferably further includes a central cooler for cooling the cooling water flowing through the first cooling flow path and the second cooling water flow path.

  The fresh water generation system of the second embodiment further includes a control device connected to the first temperature detector, the second temperature detector, the first flow rate adjustment valve, and the second flow rate adjustment valve. The control device, when the heat quantity of the cooling water led from the first circulation path and the second circulation path to the heater is lower than a predetermined heat quantity, the first flow rate adjusting valve and the second flow rate, respectively. It is preferable to open the regulating valve together and guide the cooling water to the heater.

  Further, in the fresh water generation system of the second embodiment, the control device fully opens one of the first flow rate adjustment valve and the second flow rate adjustment valve, and the other flow rate adjustment valve It is preferable that the amount of cooling water led from the first circulation path and the second circulation path to the heater is adjusted to a predetermined heat quantity by adjusting the opening amount.

  According to the fresh water generation system according to the present invention, even when the temperature of the jacket cooling water discharged from the internal combustion engine (diesel engine) is lowered, it is possible to secure a sufficient amount of heat to obtain a sufficient amount of fresh water. .

It is a schematic block diagram of the fresh water generation system which concerns on 1st Embodiment of this invention. It is a flowchart explaining the fresh water generation method of the fresh water generation system of 1st Embodiment. It is a flowchart explaining the fresh water generation method of the fresh water generation system of 1st Embodiment. It is a schematic block diagram of the modification of the fresh water generation system which concerns on 1st Embodiment of this invention. It is a flowchart explaining the fresh water generation method of the fresh water generation system of FIG. It is a flowchart explaining the fresh water generation method of the fresh water generation system of FIG. It is a schematic block diagram of the fresh water generation system which concerns on 2nd Embodiment of this invention. It is a flowchart explaining the fresh water generation method of the fresh water generation system of 2nd Embodiment. It is a flowchart explaining the fresh water generation method of the fresh water generation system of 2nd Embodiment. It is a schematic block diagram of the modification of the fresh water generation system which concerns on 2nd Embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. The fresh water generation system of the present invention transmits waste heat from an internal combustion engine (diesel engine), which is a main engine that generates a propulsion force of a ship, to seawater taken into the freshwater generator, thereby evaporating the seawater. The present invention is applied to a desalinator that cools and condenses the generated water vapor to produce desalination.

  FIG. 1 is a schematic configuration diagram of a fresh water generation system 1 according to a first embodiment of the present invention. The fresh water generation system 1 according to the first embodiment includes a fresh water generator 2 having a heater 3 for heating seawater, and air that cools combustion air supplied from a supercharger 5 to a diesel engine 4. A first cooling water passage 7 for circulating cooling water (scavenging air cooling water) to the cooler 6, a second cooling water passage 8 for circulating cooling water (jacket cooling water) for cooling the diesel engine 4, and a first cooling A first circulation path 9 that returns to the first cooling flow path 7 after being diverted from the water flow path 7 and a second circulation path 10 that returns to the second cooling flow path 9 after being diverted from the second cooling water flow path 8 are provided. .

  The fresh water generator 2 is particularly limited as long as it produces fresh water by heating seawater with the heater 3 to generate water vapor, followed by gas-liquid separation, and condensing the water vapor after gas-liquid separation. It is not something. For example, a flush type fresh water generator (for example, JP 2009-90228 A), a plate type fresh water generator (for example, JP 9-299927 A), a multi-tube type fresh water generator (for example, JP 2013-166141 A). No.), a membrane distillation type fresh water generator (for example, JP-A-6-7644), and the like. The heater 3 is a heat exchanger, for example, and heats and evaporates seawater pumped from the sea by heat exchange using waste heat discharged from the diesel engine 4 as a heat source in the heat exchanger.

  The diesel engine 4 is an internal combustion engine that uses at least one of fuel oil and fuel gas as a main fuel and burns the main fuel together with scavenging air.

  The supercharger 5 includes a turbine 50 that is driven by exhaust gas that is discharged when the diesel engine 4 burns main fuel, and a compressor 51 that compresses outside air by the rotational power of the turbine 50 and is compressed. Outside air is supplied to the diesel engine 4 as combustion air (scavenging air).

  The air cooler 6 is for cooling the scavenging air supplied from the supercharger 5 to the diesel engine 4. Since the scavenged air is adiabatically compressed and has a high temperature (about 50 ° C. to 200 ° C.), the diesel engine is cooled by the air cooler 6 for the purpose of increasing the air density (weight per unit volume). 4 is supplied.

  The 1st cooling water flow path 7 is a pipe line which circulates the scavenging air cooling water supplied to the air cooler 6, and the circulation pump 11 is connected to it. The scavenged air cooling water is circulated through the first cooling water flow path 7 by the circulation pump 11. A flow rate adjustment valve 12 and a cooler 13 are provided in the first cooling water flow path 7. The flow rate adjusting valve 12 is for adjusting the flow rate of the scavenged air cooling water supplied from the first cooling water flow path 7 to the air cooler 6. The flow rate adjustment valve 12 may be provided with a flow meter. The cooler 13 is for cooling the scavenged air cooling water that has been heated to cool the scavenged air in the air cooler 6. The cooler 13 is, for example, a heat exchanger, and cooling water is sent from a central cooler (not shown). In the cooler 13, heat exchange is performed between the scavenged air cooling water and the cooling water, The scavenging air cooling water is cooled. The flow rate adjustment valve 12 is connected to the control device 30, and the open / close state of the flow rate adjustment valve 12 is controlled by the control device 30. The first cooling water channel 7 is connected to a first circulation path 9 that diverts from the first cooling water channel 7 and then returns to the first cooling channel 7.

The first circulation path 9 is a pipe that guides the scavenging air cooling water that has been heated to a high temperature by the air cooler 6 to the heater 3. In the first circulation path 9, a temperature detector 15, a flow rate adjustment valve 14, and a heat exchanger 16 are sequentially provided on the upstream side of the heater 3. The flow rate adjusting valve 14 is for adjusting the flow rate of the scavenging air cooling water (the scavenging air cooling water guided to the heater 3) that is diverted from the first cooling water passage 7 to the first circulation passage 9. The flow rate adjustment valve 14 may be provided with a flow meter. Temperature detector 15 is for measuring the temperature T _A of the scavenging air coolant is guided to the heater 3 from the first coolant passage 7. The flow rate adjustment valve 14 and the temperature detector 15 are connected to a control device 30, and the control device 30 controls the open / close state of the flow rate adjustment valve 14 and monitors the temperature detector 15.

  The heat exchanger 16 is for heating or cooling the scavenged air cooling water led from the air cooler 6 to the heater 3 as necessary. A part of the jacket cooling water after cooling the diesel engine 4 is sent to the heat exchanger 16, and heat exchange is performed between the scavenged air cooling water and the jacket cooling water in the heat exchanger 16. The temperature of the scavenging air cooling water is adjusted. A temperature detector 17 is connected between the heat exchanger 16 and the heater 3, and the temperature of the scavenging air cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 is performed by the temperature detector 17. Has been measured. The temperature detector 17 is connected to the control device 30 and is monitored by the control device 30.

  The first circulation path 9 is provided with a temperature detector 18 and a flow rate adjusting valve 19 in this order on the downstream side of the heater 3. The temperature detector 18 is for measuring the temperature of the scavenging air cooling water discharged from the heater 3. The flow rate adjusting valve 19 is for adjusting the flow rate of scavenged air cooling water (scavenged air cooling water discharged from the heater 3) that recirculates from the first circulation path 9 to the first cooling water flow path 7. The flow rate adjustment valve 19 may be provided with a flow meter. The temperature detector 18 and the flow rate adjustment valve 19 are connected to a control device 30, and the open / close state of the flow rate adjustment valve 19 is controlled by the control device 30, and the temperature detector 18 is monitored.

  The second cooling water flow path 8 is a conduit for circulating jacket cooling water for cooling the diesel engine 4, and a circulation pump 20 is connected to the second cooling water flow path 8. The jacket cooling water is circulated through the second cooling water flow path 8 by the circulation pump 20. A flow rate adjusting valve 21 and a cooler 22 are provided in the second cooling water flow path 8. The flow rate adjusting valve 21 is for adjusting the flow rate of the jacket cooling water supplied from the second cooling water flow path 8 to the diesel engine 4. The flow rate adjustment valve 21 may be provided with a flow meter. The cooler 22 is for cooling the jacket cooling water discharged from the diesel engine 4 and having a high temperature. The cooler 22 is, for example, a heat exchanger, and cooling water is sent from a central cooler (not shown). In the cooler 22, heat is exchanged between the jacket cooling water and the cooling water, and the jacket The cooling water is cooled. The flow rate adjusting valve 21 is connected to the control device 30, and the open / close state of the flow rate adjusting valve 21 is controlled by the control device 30. The second cooling water channel 8 is connected to a second circulation path 10 that diverts from the second cooling water channel 8 and then returns to the second cooling channel 8.

The second circulation path 10 is a pipe that guides the jacket cooling water that has become high temperature due to cooling of the diesel engine 4 to the heat exchanger 16. In the second circulation path 10, a temperature detector 24 and a flow rate adjusting valve 23 are sequentially provided on the upstream side of the heat exchanger 16. The flow rate adjustment valve 23 is for adjusting the flow rate of jacket cooling water (jacket cooling water guided to the heat exchanger 16) that is diverted from the second cooling water flow path 8 to the second circulation path 10. The flow rate adjustment valve 23 is provided with a flow meter 23A. Temperature detector 24 is for measuring the temperature of the jacket cooling water T _J from the second cooling water passage 10 is guided to the heat exchanger 16. The flow rate adjusting valve 23 and the temperature detector 24 are connected to the control device 30. The control device 30 monitors the flow meter 23 </ b> A, controls the open / closed state of the flow rate adjusting valve 23, and controls the temperature detector 24. Is being monitored.

  Further, in the second circulation path 10, a temperature detector 25 and a flow rate adjustment valve 26 are sequentially provided on the downstream side of the heat exchanger 16. The temperature detector 25 is for measuring the temperature of the jacket cooling water discharged from the heat exchanger 16. The flow rate adjusting valve 26 is for adjusting the flow rate of the jacket cooling water (jacket cooling water discharged from the heat exchanger 16) that returns from the second circulation path 10 to the second cooling water flow path 8. The flow rate adjustment valve 26 may be provided with a flow meter. The temperature detector 25 and the flow rate adjustment valve 26 are connected to the control device 30. The control device 30 controls the open / close state of the flow rate adjustment valve 26 and monitors the temperature detector 25.

  Next, with reference to FIG.2 and FIG.3, the fresh water generation method by the fresh water generation system 1 which concerns on 1st Embodiment is demonstrated. Each step shown in FIGS. 2 and 3 is performed by the control device 30 reading and executing a computer program stored in a memory (not shown). 2 and 3, the scavenged air cooling water is represented by Q, and the jacket cooling water is represented by J.

First, the control device 30, at ST1, jacket cooling water from the first temperature from the cooling water flow path 7 of the scavenging air cooling water flowing through the first circulation path 9 T _A and the second cooling water passage 8 through the second circulation path 10 whether the temperature T _J is within desalination possible temperature range, it determines based on the temperature detected by the temperature detector 15 and temperature detector 24. Here, the temperature T _A of the scavenging air coolant is decreased, there is a problem that it becomes impossible to heat the seawater up to the evaporation temperature in the heater 3. Further, since seawater contains scale components such as calcium ions Ca ²⁺ and sulfate ions SO ₄ ²⁻ , when the seawater is evaporated under high temperature conditions, these scale components are applied to the surface of the heater 3. There exists a problem that it precipitates and heat exchange efficiency worsens. On the other hand, the temperature T _J of the jacket cooling water needs to be maintained within a certain temperature range necessary for stable operation of the diesel engine 4. Therefore, the temperature T _A and the temperature T _J of the jacket cooling water of the scavenging air coolant is at a temperature and scale components no trouble in operation of the apparatus is evaporated seawater at a temperature range not deposited on the surface of the heater 3 It is preferable that the temperature at which fresh water can be produced is determined. The temperature range where water can be produced is, for example, 60 ° C to 95 ° C.

In ST1, if the temperature T _A and the temperature T _J of the jacket cooling water scavenging air coolant is not together desalination possible temperature range, it is necessary to raise or lower the temperature of the cooling water, the flow proceeds to ST2, the control The device 30 adjusts the amount of cooling water sent from the central cooler to the cooler 13 and the cooler 22, respectively, and adjusts the flow rate control valve 12 and the flow rate control valve 21 to adjust the first cooling water flow path 7 and the second cooling water. The amount of cooling water flowing through the water flow path 8 is adjusted to flow through the first cooling water flow path 7 and the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and the second circulation path 10). ) Adjust the cooling water temperature. Then, the process returns to ST1.

In ST1, if the temperature T _A and the temperature T _J of the jacket cooling water of the scavenging air coolant are both the fresh water can temperature range, the process proceeds to ST3, the controller 30 opens the flow control valve 14, the first The scavenging cooling water is led from the circulation path 9 to the heater 3 to start fresh water generation. Next, the control unit 30, in ST4, whether the temperature T _A of the scavenging air cooling water flowing through the first circulation path 9 is the set temperature based on the temperature detected by the temperature detector 15 determines. Here, the set temperature is an optimum temperature range for operating the fresh water generator 2 efficiently, and is, for example, 75 ° C to 85 ° C.

In ST4, if the temperature T _A is the set temperature of the scavenging air coolant, the process proceeds to ST5, the control unit 30 performs the desalination continues to supply scavenging air cooling water set temperature to the heater 3.

On the other hand, the temperature T _A of the scavenging air coolant is not set temperature in ST4, if lower than the set temperature, the process proceeds to ST7, is necessary to raise the temperature of the scavenging air cooling water supplied to the heater 3 to a set temperature Therefore, the control device 30 determines whether the temperature T _J of the jacket cooling water flowing through the second cooling water flow path 8 is higher than the set temperature based on the temperature detected by the temperature detector 24.

In ST7, when the temperature T _J of the jacket cooling water flowing through the second cooling water passage 8 is higher than the set temperature, the control device 30, in the next ST8, by opening the flow regulating valve 23 by a predetermined amount, Jacket cooling water is guided from the second circulation path 10 to the heat exchanger 16, and the scavenged air cooling water supplied to the heater 3 is heated by the jacket cooling water in the heat exchanger 16. Then, in the next ST9, based on the temperature detected by the temperature detector 17, the controller 30 determines whether the temperature of the scavenging air cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 is the set temperature. If it is the set temperature, fresh water is produced with the flow rate adjusting valve 23 opened by a predetermined amount (ST10).

  In ST9, when the temperature of the scavenged air cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 is lower than the set temperature, the control device 30 proceeds to ST11 and detects the flow meter 23A. Based on the amount, it is determined whether or not the flow rate adjustment valve 23 is fully open (100% open state). If the flow rate adjustment valve 23 is not fully open, the process proceeds to ST12 and the flow rate adjustment valve 23 is adjusted to The scavenging air cooling water supplied to the heater 3 is further heated in the heat exchanger 16 by increasing the flow rate of the jacket cooling water led from the two circulation paths 10 to the heat exchanger 16. Then, when the temperature of the scavenging air cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 reaches the set temperature (YES in ST9), the flow rate adjustment valve 23 is further opened from a predetermined amount. Fresh water is produced (ST10). On the other hand, if the flow rate adjustment valve 23 is fully open (100% open) in ST11, the process proceeds to ST13, and the control device 30 sends the cooling device 13 and / or the cooling device 22 from the central cooler. The cooling water flowing through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and / or the second circulation path 10) is reduced. The temperature is raised and the process returns to ST1.

Returning to ST7, when the temperature T _J of the jacket cooling water flowing through the second cooling water passage 8 is lower than the set temperature, the process proceeds to ST14, the control unit 30, without opening the flow rate adjusting valve 23, the central cooler Further, the amount of cooling water sent to the cooler 13 and / or the cooler 22 is reduced to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, the first circulation path 9 and / or Alternatively, the temperature of the cooling water (supplied to the second circulation path 10) is increased, and the process returns to ST1.

Returning to ST6, when the temperature T _A of the scavenging air coolant is higher than the set temperature, because the temperature of the scavenging air cooling water supplied to the heater 3 has to be reduced to a set temperature, the process proceeds to ST15, the control unit 30 Determines whether the temperature T _J of the jacket cooling water flowing through the second cooling water flow path 8 is lower than the set temperature based on the temperature detected by the temperature detector 24.

In ST15, if the temperature T _J of the jacket cooling water flowing through the second cooling water passage 8 is lower than the set temperature, the process proceeds to ST16, the controller 30 opens the flow control valve 23 by a predetermined amount, the The jacket cooling water is guided from the two circulation paths 10 to the heat exchanger 16, and the scavenged air cooling water supplied to the heater 3 is cooled by the jacket cooling water in the heat exchanger 16. Then, in the next ST17, based on the temperature detected by the temperature detector 17, the control device 30 sets the temperature T1 of the scavenging air cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 as the set temperature. If it is the set temperature, fresh water is produced with the flow rate adjusting valve 23 opened by a predetermined amount (ST18).

  In ST17, when the temperature T1 of the scavenged air cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 is higher than the set temperature, the process proceeds to ST19, and the control device 30 detects the flow meter 23A. Based on the amount, it is determined whether or not the flow rate adjustment valve 23 is fully open (100% open state). If the flow rate adjustment valve 23 is not fully open, the flow rate adjustment valve 23 is adjusted in ST20 to obtain the second By increasing the flow rate of the jacket cooling water led from the circulation path 10 to the heat exchanger 16, the scavenged air cooling water supplied to the heater 3 is further cooled in the heat exchanger 16. When the temperature of the scavenging air cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 reaches the set temperature (YES in ST17), the flow rate adjustment valve 23 is further opened from a predetermined amount. Fresh water is produced (ST18). On the other hand, if the flow rate adjusting valve 23 is fully open (100% open) in ST19, the process proceeds to ST21, and the control device 30 sends the cooling device 13 and / or the cooling device 22 from the central cooler. The amount of cooling water to be increased is increased to flow through the first cooling water passage 7 and / or the second cooling water passage 8 (that is, supplied to the first circulation passage 9 and / or the second circulation passage 10). The temperature is lowered and the process returns to ST1.

Returning to ST15, if the temperature T _J of the jacket cooling water flowing through the second cooling water passage 8 is higher than the set temperature, the control device 30, without opening the flow rate adjusting valve 23, in the next ST22, Central cooling The amount of cooling water sent from the cooler to the cooler 13 and / or cooler 22 is increased to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, the first circulation path 9 and The temperature of the cooling water (supplied to the second circulation path 10) is decreased, and the process returns to ST1.

  According to the fresh water generation system 1 of the first embodiment, scavenged cooling water flowing through the first cooling water flow path 7 is led from the first circulation path 9 to the heater 3 and used for fresh water generation in the fresh water generation apparatus 2. A heat exchanger 16 is provided in the middle of the scavenging cooling water being guided to the heater 3, and the temperature of the scavenging cooling water is adjusted by the jacket cooling water in the heat exchanger 16. Thereby, even if it is a case where the temperature of the scavenging cooling water discharged | emitted from the air cooler 6 rises or falls, the temperature of the scavenging cooling water guide | induced to the heater 3 is suitable for the water preparation in the fresh water generator 2. Since the scavenging air cooling water having a stable temperature (heat amount) can be supplied to the fresh water generator 2 (heater 3), the amount of heat for obtaining a sufficient amount of fresh water in the fresh water generator 2 can be adjusted. Can be secured.

  The first embodiment of the present invention has been described above, but the first embodiment of the present invention is not limited to the above embodiment. For example, in the embodiment of FIG. 1, the seawater is heated by guiding the scavenged air cooling water in the first cooling water passage 7 that has been heated to a high temperature in the air cooler 6 to the heater 3. However, as shown in FIG. 4, the seawater may be heated by guiding the jacket cooling water of the second cooling water flow path 8 that has become high temperature due to cooling of the diesel engine 4 to the heater 3. In this case, the scavenged air cooling water in the first cooling water flow path 7 that has been heated to a high temperature in the air cooler 6 is used for adjusting the temperature of the jacket cooling water guided to the heater 3.

  FIG. 4 is a schematic configuration diagram of a fresh water generation system 1 that desalinates seawater with jacket cooling water. Note that the basic configuration of the embodiment of FIG. 4 is the same as the configuration of the embodiment of FIG.

  The fresh water generation system 1 according to the embodiment of FIG. 4 also includes a fresh water generator 2 having a heater 3 for heating seawater, and cools the combustion air supplied from the supercharger 5 to the diesel engine 4. A first cooling water passage 7 for circulating cooling water (scavenging air cooling water) in the air cooler 6; a second cooling water passage 8 for circulating cooling water (jacket cooling water) for cooling the diesel engine 4; A first circulation path 9 that recirculates to the first cooling flow path 7 after being diverted from the cooling water flow path 7 and a second circulation path 10 that recirculates to the second cooling flow path 9 after being diverted from the second cooling water flow path 8. I have.

  The embodiment shown in FIG. 4 differs from the embodiment shown in FIG. 1 in that the second circulation path 10 for diverting and returning to the second cooling water path 8 through which the jacket cooling water circulates is connected to the heater 3. A heat exchanger 16 is provided on the upstream side of the heater 3 in the second circulation path 10. A part of the scavenging air cooling water after the scavenging air is cooled to a high temperature in the air cooler 6 is sent to the heat exchanger 16, and in the heat exchanger 16, the jacket cooling water and the scavenging air cooling water Heat exchange is performed between the two and the temperature of the jacket cooling water is adjusted. Further, a temperature detector 27 is connected between the heat exchanger 16 and the heater 3, and the temperature detector 27 measures the temperature of the jacket cooling water after the temperature adjustment by the heat exchanger 16. Yes. The temperature detector 27 is connected to the control device 30 and is monitored by the control device 30. Further, the flow rate adjusting valve 14 is provided with a flow meter 14A, and the control device 30 monitors the flow meter 14A to control the open / closed state of the flow rate adjusting valve 14.

  Next, with reference to FIG.5 and FIG.6, the fresh water generation method by the fresh water generation system 1 which concerns on this embodiment is demonstrated. The steps shown in FIGS. 5 and 6 are also performed when the control device 30 reads and executes a computer program stored in a memory (not shown). 5 and 6, the scavenged air cooling water is represented by Q, and the jacket cooling water is represented by J.

First, the control device 30, at ST1, jacket cooling water from the first temperature from the cooling water flow path 7 of the scavenging air cooling water flowing through the first circulation path 9 T _A and the second cooling water passage 8 through the second circulation path 10 whether the temperature T _J is within desalination possible temperature range, it determines based on the temperature detected by the temperature detector 15 and temperature detector 24.

In ST1, if the temperature T _A and the temperature T _J of the jacket cooling water scavenging air coolant is not together desalination possible temperature range, it is necessary to raise or lower the temperature of the cooling water, the flow proceeds to ST2, the control The device 30 adjusts the amount of cooling water sent from the central cooler to the cooler 13 and the cooler 22, respectively, and adjusts the flow rate control valve 12 and the flow rate control valve 21 to adjust the first cooling water flow path 7 and the second cooling water. The amount of cooling water flowing through the water flow path 8 is adjusted to flow through the first cooling water flow path 7 and the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and the second circulation path 10). ) Adjust the cooling water temperature. Then, the process returns to ST1.

In ST1, if the temperature T _A and the temperature T _J of the jacket cooling water of the scavenging air coolant are both the fresh water can temperature range, the process proceeds to ST3, the controller 30 opens the flow control valve 23, the second The jacket cooling water is led from the circulation path 10 to the heater 3 to start fresh water formation. Next, the control unit 30, in ST4, whether the temperature T _J of the jacket cooling water flowing through the second circulation path 10 is set temperature, determines based on the temperature detected by the temperature detector 24.

In ST4, if the temperature T _J is the set temperature of the jacket cooling water, the process proceeds to ST5, the control unit 30 performs the desalination continues to supply the jacket cooling water set temperature to the heater 3.

On the other hand, when the temperature T _J of the jacket cooling water is lower than the set temperature, rather than a set temperature in the ST4, the process proceeds to ST7, since the temperature of the jacket cooling water supplied to the heater 3 must be raised to a set temperature, controller 30 determines whether the temperature T _a of the scavenging air cooling water flowing through the first coolant passage 7 on the basis of the temperature detected by the temperature detector 15 is higher than the set temperature.

In ST7, when the temperature T _A of the scavenging air cooling water flowing through the first coolant passage 7 is higher than the set temperature, the control device 30, in the next ST8, open the flow control valve 14 by a predetermined amount The scavenged air cooling water is guided from the first circulation path 9 to the heat exchanger 16, and the jacket cooling water supplied to the heater 3 is heated by the scavenging air cooling water in the heat exchanger 16. Then, in the next ST9, based on the temperature detected by the temperature detector 27, the control device 30 determines whether the temperature T2 of the jacket cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 is the set temperature. If it is the set temperature, fresh water is produced with the flow rate adjusting valve 14 opened by a predetermined amount (ST10).

  In ST9, when the temperature of the jacket cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 is lower than the set temperature, the control device 30 proceeds to ST11 and the detected amount of the flow meter 14A. Based on the above, it is determined whether or not the flow rate adjustment valve 14 is fully open (100% open state). If the flow rate adjustment valve 14 is not fully open, the process proceeds to ST12 and the flow rate adjustment valve 14 is adjusted to The jacket cooling water supplied to the heater 3 is further heated in the heat exchanger 16 by increasing the flow rate of the scavenged air cooling water guided from the one circulation path 9 to the heat exchanger 16. When the temperature of the jacket cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 reaches the set temperature (YES in ST9), the flow rate adjustment valve 14 is further opened from a predetermined amount. Water is used (ST10). On the other hand, if the flow rate adjustment valve 14 is fully open (100% open) in ST11, the process proceeds to ST13, and the control device 30 sends the cooler 13 and / or cooler 22 from the central cooler. The cooling water flowing through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and / or the second circulation path 10) is reduced. The temperature is raised and the process returns to ST1.

Returning to ST7, when the temperature T _A of the scavenging air cooling water flowing through the first coolant passage 7 is lower than the set temperature, the process proceeds to ST14, the control unit 30, without opening the flow control valve 14, the central cooling The amount of the cooling water sent from the cooler to the cooler 13 and / or the cooler 22 is decreased to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, the first circulation path 9 and The temperature of the cooling water (supplied to the second circulation path 10) is increased, and the process returns to ST1.

Returning to ST6, when the temperature T _J of the jacket cooling water is higher than the set temperature, because the temperature of the jacket cooling water supplied to the heater 3 has to be reduced to a set temperature, the process proceeds to ST15, the control device 30, determining whether the temperature T _a of the scavenging air cooling water flowing through the first coolant passage 7 on the basis of the temperature detected by the temperature detector 15 is lower than the set temperature.

In ST15, if the temperature T _A of the scavenging air cooling water flowing through the first coolant passage 7 is lower than the set temperature, the process proceeds to ST16, the controller 30 opens the flow control valve 14 by a predetermined amount, The scavenging air cooling water is guided from the first circulation path 9 to the heat exchanger 16, and the jacket cooling water supplied to the heater 3 is cooled by the scavenging air cooling water in the heat exchanger 16. Then, in the next ST17, the control device 30 determines whether the temperature of the jacket cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 is the set temperature based on the temperature detected by the temperature detector 27. If it is determined and the set temperature is reached, fresh water is produced with the flow rate adjusting valve 14 opened by a predetermined amount (ST18).

  In ST17, when the temperature of the jacket cooling water led to the heater 3 after the temperature adjustment by the heat exchanger 16 is higher than the set temperature, the process proceeds to ST19, and the control device 30 sets the detected amount of the flow meter 14A. Based on this, it is determined whether or not the flow rate adjustment valve 14 is fully open (100% open state). If the flow rate adjustment valve 14 is not fully open, the flow rate adjustment valve 14 is adjusted in ST20 to adjust the first circulation path. The jacket cooling water supplied to the heater 3 is further cooled in the heat exchanger 16 by increasing the flow rate of the scavenging air cooling water guided from 9 to the heat exchanger 16. When the temperature of the jacket cooling water guided to the heater 3 after the temperature adjustment by the heat exchanger 16 reaches the set temperature (YES in ST17), the flow rate adjustment valve 14 is further opened from a predetermined amount. Water is used (ST18). On the other hand, if the flow rate adjustment valve 14 is fully open (100% open) in ST19, the process proceeds to ST21, and the control device 30 sends the cooling device 13 and / or the cooling device 22 from the central cooler. The amount of cooling water to be increased is increased to flow through the first cooling water passage 7 and / or the second cooling water passage 8 (that is, supplied to the first circulation passage 9 and / or the second circulation passage 10). The temperature is lowered and the process returns to ST1.

Returning to ST15, if the temperature T _A of the scavenging air cooling water flowing through the first coolant passage 7 is higher than the set temperature, the control device 30, without opening the flow control valve 14, in the next ST22, Central The amount of cooling water sent from the cooler to the cooler 13 and / or the cooler 22 is increased to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, the first circulation path 9). And / or the temperature of the cooling water (supplied to the second circulation path 10) is lowered and the process returns to ST1.

  In the fresh water generation system 1 of this embodiment, the jacket cooling water flowing through the second cooling water flow path 8 is led from the second circulation path 10 to the heater 3 and used for fresh water generation in the fresh water generation apparatus 2. A heat exchanger 16 is provided on the way until the water is guided to the heater 3, and the temperature of the jacket cooling water is adjusted by the scavenging air cooling water in the heat exchanger 16. Thereby, even if it is a case where the temperature of the jacket cooling water discharged | emitted from the diesel engine 4 rises or falls, the temperature suitable for the fresh water generation in the fresh water generator 2 is made into the temperature of the jacket cooling water led to the heater 3. Therefore, the amount of heat for obtaining a sufficient amount of fresh water in the fresh water generator 2 can be secured. Since the temperature of the jacket cooling water tends to decrease as the efficiency of the diesel engine 4 increases, it is difficult for the jacket cooling water alone to be used for fresh water generation in the fresh water generator 2. According to the fresh water generation system 1, jacket cooling water having a stable temperature (heat amount) can be supplied to the fresh water generator 2 (heater 3).

  Next, FIG. 7 is a schematic configuration diagram of a fresh water generation system 1 ′ according to the second embodiment of the present invention. A fresh water generation system 1 ′ according to the second embodiment includes a fresh water generator 2 having a heater 3 for heating seawater, and cools combustion air supplied from a supercharger 5 to a diesel engine 4. A first cooling water passage 7 for circulating cooling water (scavenging air cooling water) in the air cooler 6; a second cooling water passage 8 for circulating cooling water (jacket cooling water) for cooling the diesel engine 4; A first circulation path 9 that recirculates to the first cooling flow path 7 after being diverted from the cooling water flow path 7 and a second circulation path 10 that recirculates to the second cooling flow path 9 after being diverted from the second cooling water flow path 8. Prepare.

  The fresh water generation system 1 according to the first embodiment described above is heated to high temperature by cooling the scavenging air in the first cooling water flow path 7 or the diesel engine 4 that has been heated by cooling the scavenging air in the air cooler 6. The seawater is heated by guiding only one of the jacket cooling water in the second cooling water flow path 8 to the heater 3. On the other hand, the fresh water generation system 1 ′ according to the second embodiment includes the scavenging air cooling water in the first cooling water flow path 7 and the diesel engine 4 that have cooled the scavenging air in the air cooler 6 to a high temperature. Both the jacket cooling water of the second cooling water flow path 8 that has become hot due to cooling can be guided to the heater 3, and depending on the situation, either scavenging cooling water or jacket cooling water, or Seawater can be heated by both scavenging cooling water and jacket cooling water.

  In the fresh water generation system 1 ′ according to the second embodiment, the structures of the fresh water generator 2, the diesel engine 4, the supercharger 5, the air cooler 6, the first cooling water flow path 7, and the second cooling water flow path 8 are described above. The configuration is the same as that of the first embodiment, and the corresponding configuration is denoted by the same reference numeral, and detailed description thereof is omitted. Also, in the following, the same reference numerals are given to the components corresponding to those of the first embodiment.

  The first circulation path 9 is a pipe that guides the scavenging air cooling water that has been heated to a high temperature by the air cooler 6 to the heater 3. In the first circulation path 9, a temperature detector 15 and a flow rate adjustment valve 14 are sequentially provided on the upstream side of the heater 3. The flow rate adjusting valve 14 is for adjusting the flow rate of the scavenging air cooling water (the scavenging air cooling water guided to the heater 3) that is diverted from the first cooling water passage 7 to the first circulation passage 9. The flow rate adjustment valve 14 is provided with a flow meter 14A. The temperature detector 15 is for measuring the temperature of the scavenging air cooling water led to the heater 3. The flow rate adjusting valve 14 and the temperature detector 15 are connected to a control device 30, the flow meter 14 </ b> A is monitored by the control device 30, the open / close state of the flow rate adjusting valve 14 is controlled, and the temperature detector. 15 is being monitored.

  The first circulation path 9 is provided with a temperature detector 18 and a flow rate adjusting valve 19 in this order on the downstream side of the heater 3. The temperature detector 18 is for measuring the temperature of the scavenging air cooling water discharged from the heater 3. The flow rate adjusting valve 19 is for adjusting the flow rate of scavenged air cooling water (scavenged air cooling water discharged from the heater 3) that recirculates from the first circulation path 9 to the first cooling water flow path 7. The flow rate adjustment valve 19 may be provided with a flow meter. The temperature detector 18 and the flow rate adjustment valve 19 are connected to a control device 30, and the open / close state of the flow rate adjustment valve 19 is controlled by the control device 30, and the temperature detector 18 is monitored.

  The second circulation path 10 is a pipe that guides the jacket cooling water that has become high temperature due to cooling of the diesel engine 4 to the heater 3. In the second circulation path 10, a temperature detector 24 and a flow rate adjusting valve 23 are sequentially provided on the upstream side of the heater 16. The flow rate adjusting valve 23 is for adjusting the flow rate of jacket cooling water (jacket cooling water guided to the heater 3) that is branched from the second cooling water flow path 8 to the second circulation path 10. The flow rate adjustment valve 23 is provided with a flow meter 23A. The temperature detector 24 is for measuring the temperature of the jacket cooling water led to the heater 3. The flow rate adjusting valve 23 and the temperature detector 24 are connected to the control device 30. The flow rate meter 23A is monitored by the control device 30, the open / closed state of the flow rate adjusting valve 23 is controlled, and the temperature detector. 24 is being monitored.

  Further, in the second circulation path 10, a temperature detector 25 and a flow rate adjusting valve 26 are sequentially provided on the downstream side of the heater 3. The temperature detector 25 is for measuring the temperature of the jacket cooling water discharged from the heater 3. The flow rate adjusting valve 26 is for adjusting the flow rate of jacket cooling water (jacket cooling water discharged from the heater 3) that recirculates from the second circulation path 10 to the second cooling water flow path 8. The flow rate adjustment valve 26 may be provided with a flow meter. The temperature detector 25 and the flow rate adjustment valve 26 are connected to the control device 30. The control device 30 controls the open / close state of the flow rate adjustment valve 26 and monitors the temperature detector 25.

  Next, with reference to FIG.8 and FIG.9, the fresh water generation method by the fresh water generation system 1 'which concerns on 2nd Embodiment is demonstrated. Each step shown in FIGS. 8 and 9 is performed by the control device 30 reading and executing a computer program stored in a memory (not shown). 8 and 9, the scavenging air cooling water is represented by Q, and the jacket cooling water is represented by J.

First, the control device 30, at ST1, jacket cooling water from the first temperature from the cooling water flow path 7 of the scavenging air cooling water flowing through the first circulation path 9 T _A and the second cooling water passage 8 through the second circulation path 10 temperature T _J, furthermore, the jacket can be supplied from the first coolant passage 7 from supply to scavenging air coolant into the first circulation path 9 flow Q _J and a second cooling water passage 8 to the second circulation path 10 Based on the amount of heat (T _J × Q _J and T _A × Q _A ) calculated from the flow rate Q _{A of the} cooling water, at least one of the scavenging air cooling water and the jacket cooling water is required as a heat source for the fresh water generator 2 Judgment is made whether or not a sufficient amount of heat is satisfied.

When the amount of heat of at least one of the scavenging air cooling water and the jacket cooling water satisfies the amount of heat necessary as a heat source for the fresh water generator 2 in ST1, the process proceeds to ST2, and the control device 30 controls the scavenging air cooling water. It is confirmed whether the amount of heat of the jacket cooling water satisfies the amount of heat necessary as a heat source of the fresh water generator 2. When the amount of heat of the scavenging air cooling water satisfies the amount of heat necessary as a heat source for the fresh water generator 2, the process proceeds to ST3, and the control device 30 opens the flow control valve 14 and starts the scavenging cooling water from the first circulation path 9. Is introduced to the heater 3 to start fresh water. Next, the control unit 30, in ST4, whether the temperature T _A of the scavenging air cooling water flowing through the first circulation path 9 is set temperature, based on the temperature detected by the temperature detector 15 determines.

In ST4, if the temperature T _A is the set temperature of the scavenging air coolant, the process proceeds to ST5, the control unit 30 performs the desalination continues to supply scavenging air cooling water set temperature to the heater 3. Meanwhile, in ST4, the temperature T _A of the scavenging air coolant if not set temperature, it is necessary to raise or lower the temperature of the scavenging air coolant to a set temperature, proceed to ST6, the control device 30, The amount of the cooling water sent from the central cooler to the cooler 13 is adjusted, and the flow rate control valve 12 is adjusted to adjust the amount of the scavenging air cooling water flowing through the first cooling water passage 7 to thereby adjust the first cooling water passage. The temperature of the scavenging air cooling water flowing through 7 (that is, supplied to the first circulation path 9) is adjusted. Then, the process returns to ST1.

On the other hand, in ST2, when the amount of heat of the jacket cooling water satisfies the amount of heat necessary as a heat source for the fresh water generator 2, the process proceeds to ST7, where the control device 30 opens the flow control valve 23 and the second circulation path. From 10, jacket cooling water is guided to the heater 3 to start water formation. Next, the control unit 30, in ST8, whether the temperature T _J of the jacket cooling water flowing through the second circulation path 10 is set temperature, determines based on the temperature detected by the temperature detector 24.

In ST8, if the temperature T _J is the set temperature of the jacket cooling water, the process proceeds to ST9, the control unit 30 performs the desalination continues to supply the jacket cooling water set temperature to the heater 3. On the other hand, if the jacket cooling water temperature _TJ is not the set temperature in ST8, it is necessary to increase or decrease the jacket cooling water temperature to the set temperature. The amount of cooling water sent from the cooler to the cooler 22 is adjusted and the flow rate control valve 21 is adjusted to adjust the amount of jacket cooling water flowing through the second cooling water channel 8 to flow through the second cooling water channel 8. The temperature of the jacket cooling water (that is, supplied to the second circulation path 10) is adjusted. Then, the process returns to ST1.

  In ST1, if both the scavenging air cooling water and the jacket cooling water have a heat quantity necessary as a heat source for the fresh water generator 2, the scavenging air cooling water and the jacket cooling water are used to produce the fresh water. The user initially sets whether or not to perform, and in ST2, for example, the determination is made based on whether or not scavenging cooling water is set in advance.

Further, in ST1, when neither the amount of heat of the scavenging air cooling water nor the jacket cooling water satisfies the amount of heat necessary as a heat source of the fresh water generator 2, the process proceeds to ST11, and the control device 30 controls the first cooling water flow path. whether from 7 temperature T _J of the jacket cooling water from the first circulation path 9 the temperature of the scavenging air cooling water flowing through the T _a and the second cooling water passage 8 through the second circulation path 10 is within the possible temperature range desalination Is determined based on the temperature detected by the temperature detector 15 and the temperature detector 24.

In ST11, if the temperature T _A and the temperature T _J of the jacket cooling water scavenging air coolant is not together desalination possible temperature range, it is necessary to raise or lower the temperature of the cooling water, the flow proceeds to ST12, control The device 30 adjusts the amount of cooling water sent from the central cooler to the cooler 13 and the cooler 22, respectively, and adjusts the flow rate control valve 12 and the flow rate control valve 21 to adjust the first cooling water flow path 7 and the second cooling water. The amount of cooling water flowing through the water flow path 8 is adjusted to flow through the first cooling water flow path 7 and the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and the second circulation path 10). ) Adjust the cooling water temperature. Then, the process returns to ST1.

In ST11, if the temperature T _A and the temperature T _J of the jacket cooling water of the scavenging air coolant are both the fresh water can temperature range, the process proceeds to ST13, the control unit 30, the scavenging air coolant and jacket cooling water It is determined whether any cooling water is mainly used as a heat source of the fresh water generator 2. In this determination, the user initializes in advance whether the scavenging air cooling water or the jacket cooling water is mainly used as the heat source of the fresh water generator 2, for example, whether the scavenging cooling water is set in advance. Judgment is made depending on why.

  When the scavenging air cooling water is initially set to be used mainly as a heat source of the fresh water generator 2, the process proceeds to ST14, where the control device 30 fully opens the flow control valve 14 and starts the scavenging air from the first circulation path 9. The cooling water is guided to the heater 3, and the flow control valve 23 is opened by a predetermined amount, and the jacket cooling water is guided from the second circulation path 10 to the heater 3 to start fresh water generation. Next, in ST15, the control device 30 determines whether or not the amount of heat necessary as a heat source for the fresh water generator 2 is satisfied based on the temperature and flow rate of the scavenging air cooling water and jacket cooling water guided to the heater 3. judge. In ST15, when the amount of heat of the scavenging air cooling water and jacket cooling water led to the heater 3 satisfies the amount of heat necessary as a heat source of the fresh water generator 2, the process proceeds to ST16, and the control device 30 Fresh water is produced with the flow rate adjusting valve 23 opened in a predetermined amount.

  On the other hand, if the amount of heat of the scavenged air cooling water and jacket cooling water led to the heater 3 does not satisfy the amount of heat necessary as a heat source of the fresh water generator 2 in ST15, the process proceeds to ST17, and the control device 30 determines whether or not the flow rate adjustment valve 23 is fully open (a state where the flow rate adjustment valve 23 is fully open) based on the detection amount of the flow meter 23A. If the flow rate adjustment valve 23 is not fully open, the flow rate adjustment valve is determined in ST18. 23 is adjusted and the amount of jacket cooling water led to the heater 3 is increased by increasing the flow rate of the jacket cooling water led from the second circulation path 10 to the heater 3. When the amount of scavenging air cooling water and jacket cooling water led to the heater 3 satisfies the amount of heat necessary as a heat source for the fresh water generator 2 (NO in ST15), the flow rate adjusting valve 23 is set to a predetermined amount. Fresh water is produced with the amount further opened (ST16). On the other hand, if the flow rate adjustment valve 23 is fully open (100% open) in ST17, the process proceeds to ST19, and the control device 30 moves from the central cooler to the cooler 13 and / or cooler 22. The amount of cooling water sent is increased to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and / or the second circulation path 10). The temperature of the cooling water is lowered and the process returns to ST1.

  Returning to ST13, when the jacket cooling water is initially set to be used mainly as a heat source of the fresh water generator 2, ST13 becomes “NO” and the process proceeds to ST20, and the control device 30 turns the flow control valve 23 on. The jacket cooling water is led from the second circulation path 10 to the heater 3 and the flow rate control valve 14 is opened by a predetermined amount, and the scavenging air cooling water is led from the first circulation path 9 to the heater 3 to produce fresh water. Start. Next, in ST21, based on the temperature and flow rate of the scavenging air cooling water and jacket cooling water led to the heater 3, the control device 30 determines whether or not the amount of heat necessary as a heat source for the fresh water generator 2 is satisfied. judge. In ST21, when the heat amount of the scavenging air cooling water and jacket cooling water led to the heater 3 satisfies the heat amount necessary as a heat source of the fresh water generator 2, the process proceeds to ST22, and the control device 30 Fresh water is produced with the flow rate adjusting valve 23 opened in a predetermined amount.

  On the other hand, if the amount of heat of the scavenging air cooling water and jacket cooling water led to the heater 3 does not satisfy the amount of heat necessary as a heat source of the fresh water generator 2 in ST21, the process proceeds to ST23, and the control device 30 determines whether or not the flow rate adjustment valve 14 is fully open (a state in which the flow rate adjustment valve 14 is fully opened) based on the detection amount of the flow meter 14A. If the flow rate adjustment valve 14 is not fully open, the flow rate adjustment valve 14 is determined in ST24. 14 is adjusted to increase the flow rate of the scavenged air cooling water guided from the first circulation path 9 to the heater 3, thereby increasing the amount of heat of the scavenged air cooling water guided to the heater 3. When the amount of scavenging air cooling water and jacket cooling water led to the heater 3 satisfies the amount of heat necessary as a heat source for the fresh water generator 2 (NO in ST21), the flow rate adjustment valve 14 is set to a predetermined amount. Fresh water is produced with the amount further opened (ST22). On the other hand, if the flow rate adjustment valve 14 is fully open (100% open) in ST23, the process proceeds to ST25, and the control device 30 moves from the central cooler to the cooler 13 and / or cooler 22. The amount of cooling water sent is increased to flow through the first cooling water flow path 7 and / or the second cooling water flow path 8 (that is, supplied to the first circulation path 9 and / or the second circulation path 10). The temperature of the cooling water is lowered and the process returns to ST1.

  According to the fresh water generation system 1 ′ of the second embodiment described above, the scavenging cooling water flowing through the first cooling water flow path 7 is guided from the first circulation path 9 to the heater 3, and the jacket flows through the second cooling water flow path 8. The cooling water is guided from the second circulation path 10 to the heater 3 and used for fresh water generation in the fresh water generator 2. Thereby, even if the temperature of the scavenging cooling water discharged from the air cooler 6 increases or decreases, or the temperature of the jacket cooling water discharged from the diesel engine 4 increases or decreases, the heater By appropriately adjusting the temperature and flow rate of the scavenging cooling water and jacket cooling water guided to 3, the amount of heat for obtaining a sufficient amount of fresh water in the fresh water generator 2 can be secured. The temperature of the jacket cooling water tends to decrease as the efficiency of the diesel engine 4 increases, and if the temperature of the scavenging cooling water fluctuates, the jacket cooling water or the scavenging air cooling water alone does not produce water. Although it becomes difficult to use it for fresh water generation in the device 2, according to the fresh water generation system 1 'of the second embodiment, it is possible to supply cooling water with a stable amount of heat to the fresh water generation device 2 (heater 3). .

  The second embodiment of the present invention has been described above, but the present invention is not limited thereto, and various modifications can be made without departing from the spirit of the present invention.

  For example, in the fresh water generation system 1 ′ of the second embodiment, as shown in FIG. 10, the upstream side of the heater 3 in the first circulation path 9 and the upstream of the heater 3 in the second circulation path 10. A first connection path 28 that connects the first circulation path 9 to the downstream side of the heater 3 in the first circulation path 9 and a downstream section of the second circulation path 10 from the heater 3. A second connection path 29 to be connected is provided. In addition, the flow rate adjustment valve 31 may be provided in the first connection path 28 and the flow rate adjustment valve 32 may be provided in the second connection path 29. Each flow rate adjusting valve 31, 32 is for adjusting the flow rate of the cooling water that is diverted / refluxed from the first circulation path 9 to the second circulation path 10 or that is diverted / refluxed from the second circulation path 10 to the first circulation path 9. It is connected to the control device 30, and the control device 30 controls the open / close state of the flow rate adjusting valves 31, 32.

  In the fresh water generation system 1 ′ of the embodiment of FIG. 10, when fresh water is formed using only one of the scavenged air cooling water and the jacket cooling water, for example, the fresh water is generated using the jacket cooling water. When performing, normally (embodiment of FIG. 7), the flow control valves 14 and 19 are closed, and the flow control valves 23 and 26 are opened, so that only the jacket cooling water is supplied to the heater 3 by the second circulation path 10. However, in this case, the flow rate control valves 31 and 32 are opened, and the jacket cooling water flowing through the second circulation path 10 is diverted from the first connection path 28 to the first circulation path 9. Also, the jacket cooling water is guided to the heater 3 to produce water. And the jacket cooling water of the 1st circulation path 9 discharged | emitted from the heater 3 is all returned to the 2nd cooling water flow path 8 by making it return to the 1st circulation path 9 from the 2nd connection path 29. FIG. According to the fresh water generation system 1 ′ of the embodiment of FIG. 10, the jacket cooling water is guided to the heater 3 using not only the second circulation path 10 but also the normally unused first circulation path 9. By performing heat exchange with seawater at 3, the heat transfer surface (portion used for heat exchange) of the heater 3 can be used effectively without being left behind. Thereby, even if there is a change in the heat source (scavenging air cooling water or jacket cooling water) of the fresh water generator 2, the operating efficiency of the fresh water generator 2 can always be kept at the highest level regardless of this. ,It is valid.

  In the fresh water generation system 1 ′ of the embodiment of FIG. 10, when fresh water is generated using scavenging air cooling water, the flow control valves 23 and 26 are normally closed (the embodiment of FIG. 7). By opening the flow control valves 14 and 19, only the scavenged cooling water is guided to the heater 3 by the first circulation path 9. In this case, the flow control valves 31 and 32 are opened and the scavenging gas flowing through the first circulation path 9. By diverting the cooling water from the first connection path 28 to the second circulation path 10, not only the first circulation path 9 but also the second circulation path 10 leads the scavenged cooling water to the heater 3, thereby producing fresh water. It can be carried out.

DESCRIPTION OF SYMBOLS 1,1 'Fresh water generation system 2 Fresh water generator 3 Heater 7 1st cooling water flow path 8 2nd cooling water flow path 9 1st circulation path 10 2nd circulation path 30 Control apparatus

Claims (10)

In a freshwater production system that produces fresh water from seawater introduced to a ship using waste heat from an internal combustion engine mounted on the ship,
A fresh water generator having a heater for heating seawater;
A first cooling water passage for circulating cooling water to an air cooler for cooling combustion air supplied from the supercharger to the internal combustion engine;
A second cooling water flow path for circulating cooling water for cooling the internal combustion engine;
A first circulation path that diverts from the first cooling water flow path and then returns to the first cooling flow path;
A second circulation path that diverges from the second cooling water flow path and then returns to the second cooling flow path,
The cooling water flowing through the first circulation path or the cooling water flowing through the second circulation path is guided to the heater to exchange heat with seawater,
Of the first circulation path and the second circulation path, the circulation path through which the cooling water led to the heater flows has cooling water flowing through the circulation path and another circulation path upstream of the heater. A heat exchanger for exchanging heat with the flowing cooling water is provided, and a flow rate adjusting valve for adjusting the flow rate of the cooling water led to the heat exchanger is provided on the upstream side of the heat exchange device in the other circulation path. Fresh water system provided.   The fresh water generation system according to claim 1, further comprising a central cooler for cooling the cooling water flowing through the first cooling flow path and the second cooling water flow path.   Of the first circulation path and the second circulation path, a circulation path through which the cooling water led to the heater flows includes a first temperature detector and a second temperature detection on the upstream side and the downstream side of the heat exchanger. The fresh water generation system according to claim 1 or 2, wherein a third temperature detector is provided upstream of the heat exchange device in the other circulation path. A control device connected to the first temperature detector, the second temperature detector, the third temperature detector, and the flow rate adjustment valve;
The control device measures the temperature of the cooling water in the other circulation path when the temperature of the cooling water led to the heater is lower than a set temperature, and the flow rate when the temperature is higher than the set temperature. The fresh water generation system of Claim 3 which opens a regulating valve and guides the said cooling water to the said heat exchanger.   The control device measures the temperature of the cooling water in the other circulation path when the temperature of the cooling water led to the heater is higher than a set temperature, and the flow rate when the temperature is lower than the set temperature. The fresh water generation system of Claim 4 which opens a regulating valve and guides the said cooling water to the said heat exchanger.   The control device measures the temperature of the cooling water in the other circulation path when the temperature of the cooling water led to the heater is higher than a set temperature, and when the temperature is higher than the set temperature, The fresh water generation system according to claim 4, wherein a cooler is controlled to reduce a temperature of the cooling water flowing through the first cooling flow path and the second cooling water flow path. In a freshwater production system that produces fresh water from seawater introduced to a ship using waste heat from an internal combustion engine mounted on the ship,
A heater for heating seawater;
A first cooling water passage for circulating cooling water to an air cooler for cooling combustion air supplied from the supercharger to the internal combustion engine;
A second cooling water flow path for circulating cooling water for cooling the internal combustion engine;
A first circulation path that branches off from the first cooling water flow path and then returns to the first cooling flow path;
A second circulation path that diverges from the second cooling water flow path and then returns to the second cooling flow path,
The cooling water flowing through the first circulation path and the cooling water flowing through the second circulation path are guided to the heater and configured to exchange heat with seawater.
In the first circulation path, a first temperature detector and a first flow rate adjusting valve for adjusting a flow rate of cooling water led to the heater are provided on the upstream side of the heater,
The second circulation path is provided with a second temperature detector and a second flow rate adjusting valve for adjusting a flow rate of cooling water led to the heater on the upstream side of the heater. .   The fresh water generation system according to claim 7, further comprising a central cooler for cooling the cooling water flowing through the first cooling flow path and the second cooling water flow path. A control device connected to the first temperature detector, the second temperature detector, the first flow rate adjustment valve, and the second flow rate adjustment valve;
When the amount of cooling water led from the first circulation path and the second circulation path to the heater is lower than a predetermined amount of heat, the control device controls the first flow rate adjustment valve and the second flow rate adjustment. The fresh water generation system according to claim 7 or 8, wherein both the valves are opened to guide the cooling water to the heater.   The control device fully opens the flow rate adjustment valve of either the first flow rate adjustment valve or the second flow rate adjustment valve, and adjusts the amount of opening of the other flow rate adjustment valve, so that the first circulation path and The fresh water generation system according to claim 9, wherein a heat amount of the cooling water led from the second circulation path to the heater is set to a predetermined heat amount.

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