JP3607350B2 - Cooling structure for exhaust equipment for watercraft - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a cooling structure for an exhaust device for a watercraft that cools an exhaust pipe in the vicinity of an engine as a double pipe structure and flows exhaust gas and cooling water to a water lock via a common rubber hose.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a water-borne ship includes a water jet propulsion device that uses a two-cycle engine as a power source, and is configured such that an occupant travels while holding a steering handle across a seat on a hull. The exhaust system used for this type of surface-traveling ship is cooled by engine cooling water because it cannot be expected to be cooled by wind during cruising because it is housed in the hull.
[0003]
In this way, when cooling the exhaust device with cooling water, the expansion part connected to the engine has a double pipe structure consisting of an inner pipe and an outer pipe, and cooling water is allowed to flow between these two pipes. The structure which discharged | emitted cooling water to the exhaust passage in the downstream edge part was taken. The cooling water discharged to the exhaust passage passes through a rubber hose connected to the expansion portion and flows into the water lock together with the exhaust gas. After extending upward from the water lock, the cooling water is substantially inverted U-shaped. It was discharged to the propeller chamber of the water jet propulsion device through the exhaust pipe.
[0004]
The water lock is used to prevent water from flowing back from the exhaust outlet on the propeller chamber side to the engine side when the hull rolls over, and the pressure of the exhaust gas when cooling water accumulates to some extent in the exhaust expansion chamber. Is pushed out into the exhaust pipe.
[0005]
[Problems to be solved by the invention]
However, as described above, the flow rate of the cooling water is a problem when the cooling water is pushed out from the water lock by the pressure of the exhaust gas. That is, as the flow rate of the cooling water increases, the cooling water is frequently pushed out from the water lock, and the exhaust resistance increases, which hinders the engine output from being increased.
[0006]
Such a problem can be solved by not discharging cooling water into the exhaust passage, but in this case, the rubber hose that communicates the expansion portion and the water lock can be cooled by the cooling water. It becomes impossible. Since the rubber hose is used to prevent the vibration of the engine from being transmitted to the water jet propulsion device and the hull through the exhaust system, it cannot be replaced with a rigid body such as a pipe. Moreover, considering the cost, it cannot be replaced with an expensive metal bellows hose.
[0007]
The present invention has been made to solve such a problem, and it is possible to prevent the rubber hose from being overheated while suppressing the cooling water flowing in the water lock to reduce the exhaust resistance. With the goal.
[0008]
[Means for Solving the Problems]
In the cooling structure for an exhaust device for a watercraft according to the first aspect of the present invention, double pipe parts through which cooling water flows are provided at two locations on the upstream side and the downstream side of the exhaust pipe member, and these double pipe parts are connected to each other. Is connected with the cooling water pipe , one end of the hose with the other end connected to the discharge port is connected to the upstream double pipe part, and the cooling water outlet is connected to the downstream end of the downstream double pipe part. A cooling water outlet that communicates the cooling water passage with the exhaust passage is provided in a state where the cross-sectional area of the passage is narrowed by fitting an annular seal rubber formed with a concave groove , and covers the cooling water outlet. In this way, a rubber hose is connected.
[0009]
According to a second aspect of the present invention, there is provided a cooling structure for an exhaust device for a watercraft, wherein the downstream double pipe portion of the exhaust pipe member has a downward slope. Inclined and discharged into the rubber hose extending in a substantially horizontal direction from the connecting portion with the exhaust pipe member, and the cooling water is discharged from the left and right sides when viewed from the upstream side of the exhaust passage. .
[0010]
According to a third aspect of the present invention, there is provided a cooling structure for an exhaust device for a watercraft, according to the first aspect, wherein the upstream double pipe portion and the downstream double pipe in an exhaust pipe member are provided. The temperature sensor which detects the temperature of an exhaust passage wall surface is attached to the single pipe part between these parts.
[0011]
[Action]
According to the first aspect of the present invention, the passage of the cooling water has a small passage cross-sectional area at the inlet of the cooling water pipe and the cooling water outlet of the downstream double pipe portion, so that the cooling water flowing into the water lock is reduced.
[0012]
According to the second invention, the cooling water discharged from the cooling water outlet of the downstream double pipe portion into the rubber hose is pushed by the exhaust gas, and above the bent portion where the flow rate of the exhaust gas is relatively increased. Flowing.
[0013]
According to the third aspect of the present invention, the flow path of the cooling water has a small passage cross-sectional area at the inlet of the cooling water pipe, so that the cooling water flowing into the water lock is reduced. Further, since the single pipe portion is difficult to be cooled by the cooling water, the accurate temperature of the exhaust pipe member is detected by the temperature sensor.
[0014]
【Example】
Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS.
FIG. 1 is a side view of a watercraft using a cooling structure for an exhaust device according to the present invention. In FIG. FIG. 2 is a plan view showing a schematic configuration of a watercraft, FIG. 3 is a cross-sectional view of an exhaust pipe member according to the present invention, and FIG. 4 is a right side view of a downstream end of the exhaust pipe member viewed from the right side of the hull. FIG. 5 is a view taken in the direction of arrow A in FIG. 4, and FIG. 6 is a sectional view taken along line VI-VI in FIG.
[0015]
In these drawings, reference numeral 1 denotes a watercraft according to the present embodiment, and 2 denotes a hull of the watercraft 1. In this surface traveling boat 1, an occupant sits straddling a seat 3 on a hull 2 and travels while grasping a steering handle 4 provided in front of the seat 3. In addition, a step (not shown) for placing a passenger's foot is formed integrally with the hull 2 on both the left and right sides of the seat 3.
[0016]
In the hull 2, an engine chamber 6 is provided on the front side of the bulkhead 5 standing on the ship bottom 2b, and a pump chamber 7 is provided on the rear side. In the engine chamber 6, an engine 8 is mounted at a position below the seat 3 and at the center in the left-right direction of the hull 2, and a fuel tank 9 is disposed at a position in front of the engine 8.
[0017]
The engine 8 is a two-cycle two-cylinder type and has a structure in which two cylinders are arranged at the front and rear, and is connected to a jet pump 10 provided at the rear of the hull. The engine 8 and the jet pump 10 constitute a water jet propulsion device that drives the surface traveling boat 1.
[0018]
The engine 8 has an intake device 11 connected to the right side of the hull of the crankcase 8a as shown in FIG. 2, and an exhaust device 12 connected to the left side of the hull of the cylinder body 8b (FIG. 1). The intake device 11 has a structure in which a carburetor (not shown) is connected to the crankcase 8a via an intake pipe (not shown), and an intake silencer 11a is connected to the upstream end of the carburetor. It has become.
[0019]
The exhaust device 12 is connected to the cylinder body 8 b to extend the exhaust passage to the side, and extends from the front end of the lead-out portion 13 to the front side of the hull and above the cylinder portion of the engine 8. After that, the exhaust pipe member 14 extending rearwardly downward to the hull and forming an exhaust expansion chamber therein is disposed at the bottom of the hull on the left side of the hull, and a rubber hose 15 is provided at the rear end of the exhaust pipe member 14. The water lock 16 communicated with each other and the upper end of the rear end of the water lock 16 so as to cross the upper portion of the jet pump 10 and extend rearwardly downward on the right side of the hull from the jet pump 10. The exhaust pipe 17 connected to the side wall of the propeller chamber of the engine, and the exhaust gas of the engine 8 is opened to the side wall of the propeller chamber of the jet pump 10 It has a structure to discharge to the propeller chamber from 10a.
[0020]
Since the exhaust device 12 is housed in the hull 2, the exhaust device 12 is structured to be cooled by engine cooling water because cooling by wind during traveling cannot be expected. That is, as shown in FIG. 3, the exhaust pipe member 14 has a double pipe structure, and engine cooling water is supplied between the inner pipe portion and the outer pipe portion, and the exhaust gas in the rubber hose 15 is exhausted from the exhaust pipe member 14. The cooling is performed by discharging the cooling water into the passage. The cooling water discharged to the rubber hose 15 flows into the water lock 16 and accumulates in the water lock 16 to some extent, and then is pushed out to the exhaust pipe 17 by the pressure of the exhaust gas and discharged into the propeller chamber together with the exhaust gas. The The exhaust device 12 of the present embodiment has the same structure as the conventional structure on the downstream side from the rubber hose 15.
[0021]
Here, the structure of the exhaust pipe member 14 will be described in detail. The exhaust pipe member 14 includes an upstream side pipe member 18 connected to the lead-out part 13, and a downstream side inner part connected to a downstream end portion of the upstream side pipe member 18 via a connecting pipe member 19 and a connecting outer pipe 20. The pipe 21 and the downstream outer pipe 22 and a seal rubber 23 fixed to the downstream end of the downstream outer pipe 22 are configured.
[0022]
The upstream pipe member 18 is formed integrally with an inner pipe portion 18a and an outer pipe portion 18b by, for example, the lost wax method, and a cooling water passage W1 is formed between these two portions, and is directed toward the front side of the hull. It is formed in a substantially U shape in a side view so as to be convex. Further, the upstream pipe member 18 has a lower end connected to the outlet 13 so that the exhaust passage S1 in the inner pipe 18a communicates with an exhaust passage (not shown) of the outlet 13 and the cooling water The passage W1 is formed so as to communicate with a cooling water outlet (not shown) of the outlet 13. The downstream end portion of the upstream pipe member 18 is formed so as to be directed obliquely downward and downward.
[0023]
The connecting tube member 19 is formed by integrally forming an inner tube portion 19a and an outer tube portion 19b, and the upstream end portion of the inner tube portion 19a is connected to the inner tube portion 18a of the upstream tube member 18. While being connected via the band 24, the upstream end of the outer pipe portion 19 b is connected to the outer pipe portion 18 b of the upstream pipe member 18 via the connecting outer pipe 20. The connecting outer pipe 20 is formed by joining a downstream metal pipe 20b to an upstream rubber pipe 20a, and an upstream end of the rubber pipe 20a is connected to the upstream pipe member 18. The downstream end portion of the metal pipe body 20b is bolted to the outer pipe portion 19b of the connecting pipe member 19 by a connecting bolt 25.
[0024]
With such a configuration, the cooling water passage W2 communicating with the cooling water passage W1 of the upstream side pipe member 18 is formed inside the outer pipe portion 19b of the connecting pipe member 19 and the outer pipe 20 for connection. Further, an exhaust passage S2 communicating with the exhaust passage S1 is formed inside the inner pipe portion 19a of the connecting pipe member 19. Note that one end of a pilot water hose 27 is connected to the highest portion of the cooling water passage W2 through a cooling water outlet pipe 26 formed integrally with the rubber pipe 20a. The other end of the hose 27 is connected to a pilot water discharge port (not shown) on the side wall of the hull 2.
[0025]
That is, when the uppermost part of the cooling water passage W2 is filled with the cooling water, a part of the cooling water in the cooling water passage W2 passes through the hose 27 and is discharged out of the pilot water discharge port. For this reason, the occupant can visually confirm that the cooling water is supplied to the cooling water system with such an amount of water that reaches the uppermost portion of the exhaust pipe member 14.
[0026]
The downstream inner pipe 21 is integrally formed with a connecting flange 21a positioned at the upstream end and a pipe section 21 having a circular cross section extending from the downstream end to the downstream end. The outer tube 22 is inserted from the upstream side. Then, the downstream end face of the connecting flange 21a is brought into close contact with the upstream end face of the downstream outer tube 22, and the downstream outer peripheral portion of the tube portion 21b is attached to the inner step portion 22a of the downstream outer tube 22. The connection bolt 25 is fixed to the connection pipe member 19 with the connection bolt 25 in close contact therewith. The connecting bolt 25 passes through the metal pipe body 20b of the connecting outer pipe 20, the connecting pipe member 19, and the connecting flange 21a, and is screwed to the downstream outer pipe 22.
[0027]
The connecting flange 21a is formed with a number of through holes 21c that open to the upstream end face and the downstream end face at intervals in the circumferential direction of the connecting flange 21a. Further, the downstream end of the downstream inner pipe 21 extends downstream from the seal member 28, and is formed so that the opening diameter is smaller than the inner diameter of the upstream pipe portion 21b.
[0028]
By connecting the downstream inner pipe 21 and the downstream outer pipe 22 to the connecting pipe member 19 in this way, a cooling water passage W3 communicating with the cooling water passage W2 through the through hole 21c of the connecting flange 21a is provided. It is formed between both tubes 21 and 22. At the same time, an exhaust passage S3 communicating with the exhaust passage S2 is formed inside the downstream inner pipe 21. The cooling water passages W2 and W3 and the exhaust passages S2 and S3 described above are connected to the downstream end of the upstream pipe member 18 formed so as to be directed obliquely downward and downward, and the connecting pipe member and the connecting outer pipe 20 are connected. Since the inner pipe 21 is formed by connecting the downstream side inner pipe 21 in this order on the same axis, it extends rearwardly downward as shown in FIG.
[0029]
In addition, a communication passage 21d for communicating the cooling water passage W3 with a space downstream of the seal member 28 (an exhaust passage communicating with the exhaust passage S3) is formed at the downstream end of the downstream inner pipe 21. doing. 21 d of this communicating path opens to the outer peripheral surface used as the wall surface of the cooling water path W3 in the pipe part 21b of the downstream inner pipe 21, and the other end extends downstream from the seal member 28 in the pipe part 21b. Is opened toward the downstream side in the exhaust flow direction.
[0030]
The downstream outer tube 22 is inclined so that the downstream end gradually extends downward from the portion corresponding to the downstream end of the downstream inner tube 21 toward the downstream side. A substantially cylindrical inner tube portion 22b is integrally formed inside the end portion so as to form a double tube structure. The rubber hose 15 is fitted and fixed to the outer peripheral surface of the downstream end. As shown in FIG. 1, the rubber hose 15 is bent from the connecting portion with the downstream outer pipe 22 and extends substantially horizontally so as to go to the rear of the hull 2.
[0031]
Between the outer peripheral surface of the inner tube portion 22b and the inner peripheral surface of the outer peripheral portion of the downstream outer tube 22, an annular space having a cross section that opens downward is formed. The seal rubber 23 is press-fitted and fixed to the downstream end of the downstream outer tube 22 so as to close the opening of this space. Further, this space communicates with the cooling water passage W3 through a cooling water pipe 29 connected to the downstream outer pipe 22.
[0032]
As shown in FIGS. 4 and 5, the cooling water pipe 29 is connected to the lower part of the downstream outer pipe 22 corresponding to the downstream end of the cooling water passage W3 and on the right side of the hull. The end is connected to a part corresponding to the upper part of the space in the downstream outer pipe 22 and a part on the rear side of the hull. Thereby, the space communicated with the cooling water passage W3 becomes the cooling water passage W4. In addition, the center side of the annular coolant water passage W4 is an exhaust passage S4 communicating with the exhaust passage S3 in the downstream inner pipe 21.
[0033]
In FIG. 3 to FIG. 5, what is indicated by reference numeral 30 provided on the outer peripheral portion on the right side of the hull of the downstream outer pipe 22 is a temperature sensor. The temperature sensor 30 detects the temperature of the downstream outer pipe 22 corresponding to the downstream end of the downstream inner pipe 21 (the part where the cooling water passage is not formed), and sends a temperature signal to a warning device (not shown). Is output. This warning device turns on a warning lamp (not shown) provided near the steering handle 4 when the temperature of the downstream outer tube 22 detected by the temperature sensor 30 reaches a preset temperature. It is configured. The set temperature is set to a temperature slightly lower than the use limit temperature of the rubber hose 15.
[0034]
As shown in FIG. 6, the seal rubber 23 is formed in an annular shape in cross section as shown in FIG. 6, and has concave grooves 23 a extending along the axial direction of the seal rubber 23 at two locations on the outer peripheral portion. These concave grooves 23a are disposed at portions on the left and right sides when the exhaust passage S4 is viewed from the upstream side. That is, the cooling water passage W4 communicates with the exhaust passage S4 and the internal space of the rubber hose 15 through these concave grooves 23a. The concave groove 23a constitutes a cooling water outlet of the downstream double pipe portion referred to in the present invention. By using the concave groove 23a as a cooling water outlet, the cooling water passage W4 can be used in a state where the passage cross-sectional area is narrower than when cooling water is discharged from the cooling water passage W4 into the exhaust passage without using the seal rubber 23. Can be communicated with the exhaust passage.
[0035]
As described above, the exhaust pipe member 14 is provided with double pipe portions at two locations between the upstream end and the downstream end of the downstream inner tube 21 and the downstream end of the downstream outer tube 22. These double pipe parts are configured to communicate with each other through a cooling water pipe 29. Further, the temperature sensor 30 is attached to a single pipe portion between the double pipe portions in the downstream outer pipe 22.
[0036]
That is, in the exhaust device 12 provided with the exhaust pipe member 14, the exhaust gas of the engine 8 flows into the exhaust passage S1 from the engine-side lead-out portion 13, and passes through the exhaust passages S1 to S4 in this order, so that the exhaust pipe member 14 After that, it is discharged from the exhaust outlet 10a into the propeller chamber through the exhaust system of the rubber hose 15 → the water lock 16 → the discharge pipe 17.
[0037]
Further, the cooling water flowing into the cooling water passage W1 of the exhaust pipe member 14 from the engine-side lead-out portion 13 flows into the cooling water passage W3 from the cooling water passage W1 through the cooling water passage W2 and the through hole 21c. Almost the whole amount flows into the cooling water passage W4 through the cooling water pipe 29.
A part of the cooling water in the cooling water passage W3 flows out into the single pipe portion (in the exhaust passage S4) of the downstream outer pipe 22 through the communication passage 21d provided in the downstream inner pipe 21. This cooling water hits the inner surface of the single pipe portion on the downstream side of the portion corresponding to the temperature sensor 30 to cool it.
[0038]
The cooling water that has flowed from the cooling water pipe 29 into the cooling water passage W4 is discharged through the concave groove 23a of the seal rubber 23 into the exhaust passage. Thus, the cooling water is discharged into the exhaust passage, whereby the rubber hose 15 is cooled from the inner surface.
[0039]
Therefore, when the above-described exhaust pipe member 14 is used, the passage of the cooling water has a small passage cross-sectional area at the inlet of the cooling water pipe 29 and the inlet of the concave groove 23a, so that it is discharged to the rubber hose 15 and flows into the water lock 16. Cooling water to be reduced.
[0040]
In addition, the downstream double pipe portion serving as the cooling water passage W4 is inclined so as to gradually extend downward toward the downstream side, and the rubber hose 15 is bent from the portion connected to the double pipe portion. Since the cooling water is discharged from both the left and right sides by the concave groove 23a of the seal rubber 23 into the rubber hose 15, the cooling water discharged from the concave groove 23a into the rubber hose 15 is pushed by the exhaust gas. As a result, the flow rate of the exhaust gas in the rubber hose 15 flows to a portion where the flow rate of the exhaust gas is relatively large, that is, the inner surface on the upper side of the bent portion. The position of the inner surface on the upper side of the bent portion is indicated by reference numeral 15a in FIG.
For this reason, even if it employ | adopts the structure which regulates the flow volume of a cooling water as mentioned above, a cooling water will flow efficiently to the site | part which becomes high temperature of the rubber hose 15 efficiently.
[0041]
Furthermore, since the portion to which the temperature sensor 30 is attached in the single pipe portion of the downstream outer tube 22 is difficult to be cooled by the cooling water, the temperature sensor 30 can detect the accurate temperature of the downstream outer tube 22. As a result, the temperature of the rubber hose 15 can be accurately obtained while being indirect based on the output of the temperature sensor 30.
[0042]
【The invention's effect】
As described above, the cooling structure for the watercraft exhaust system according to the first aspect of the present invention provides the double pipe portion through which the cooling water flows at two locations, the upstream side and the downstream side of the exhaust pipe member. The double pipes are communicated with each other by a cooling water pipe , one end of a hose whose other end is connected to the discharge port is connected to the upstream double pipe part, and the downstream side of the downstream double pipe part is connected to the downstream end. A cooling water outlet is provided for connecting the cooling water passage to the exhaust passage in a state in which the cross-sectional area of the passage is narrowed by fitting an annular seal rubber having a concave groove forming the cooling water outlet; Since the rubber hose is connected so as to cover the water outlet, the cooling water flow path has a small passage cross-sectional area at the inlet of the cooling water pipe and the cooling water outlet of the downstream double pipe section. Decrease.
For this reason, since cooling water is not frequently pushed out from the water lock, the exhaust resistance becomes smaller than the conventional one, and the output of the engine can be increased.
[0043]
According to a second aspect of the present invention, there is provided a cooling structure for an exhaust device for a watercraft, wherein the downstream double pipe portion of the exhaust pipe member has a downward slope. Inclined and inserted into the rubber hose extending in a substantially horizontal direction from the connection with the exhaust pipe member, the cooling water is discharged from the left and right sides when viewed from the upstream side of the exhaust passage. The cooling water discharged into the rubber hose from the cooling water outlet of the double pipe portion is pushed by the exhaust gas and flows above the bent portion where the flow rate of the exhaust gas is relatively increased.
For this reason, since the cooling water flows efficiently and substantially evenly in the part where the temperature of the rubber hose tends to be high, an increase in temperature can be suppressed even if the amount of the cooling water is small.
[0044]
According to a third aspect of the present invention, there is provided a cooling structure for an exhaust device for a watercraft, according to the first aspect, wherein the upstream double pipe portion and the downstream double pipe in an exhaust pipe member are provided. Since the temperature sensor that detects the temperature of the wall of the exhaust passage is attached to the single pipe part between the part and the single pipe part, the accurate temperature of the exhaust pipe member can be detected by the temperature sensor because the single pipe part is difficult to be cooled by the cooling water. it can.
For this reason, since the temperature of the rubber hose can be obtained accurately indirectly based on the output of the temperature sensor, the cooling water flowing through the rubber hose is reduced as described above, and then sand or the like is contained in the cooling water system. Even if foreign matter accumulates and the flow rate of the cooling water further decreases, it is possible to adopt a configuration in which some warning is issued before the rubber hose reaches the use limit temperature.
[Brief description of the drawings]
FIG. 1 is a side view of a watercraft that employs a cooling structure for an exhaust device according to the present invention, in which a water jet propulsion device portion is cut away.
FIG. 2 is a plan view showing a schematic configuration of the surface traveling ship.
FIG. 3 is a cross-sectional view of an exhaust pipe member according to the present invention.
FIG. 4 is a right side view showing a state in which the downstream end of the exhaust pipe member is viewed from the right side of the hull.
5 is a view taken in the direction of arrow A in FIG.
6 is a cross-sectional view taken along line VI-VI in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Surface traveling ship, 2 ... Hull, 8 ... Engine, 12 ... Exhaust device, 14 ... Exhaust pipe member, 15 ... Rubber hose, 16 ... Water lock, 18 ... Upstream side pipe member, 19 ... Connecting pipe member, 20 ... Outer pipe for connection, 21 ... downstream inner pipe, 22 ... downstream outer pipe, 22b ... inner pipe section, 23 ... seal rubber, 23a ... concave groove, 29 ... cooling water pipe.

Claims (3)

An exhaust pipe member (14) in which a cooling water passage is formed around the exhaust passage by adopting a double pipe structure, the cooling water of the double pipe portion is discharged into the exhaust passage, and the cooling water and the exhaust gas are discharged. In the cooling structure of a watercraft exhaust device that flows from the exhaust pipe member (14) to the water lock (16) through the rubber hose (15) , the double pipe portions are arranged upstream and downstream of the exhaust pipe member (14). These two pipe sections are communicated with each other by a cooling water pipe (29) formed separately from the exhaust pipe member, and the other end is connected to the upstream double pipe section. One end of the hose (27) connected to the annular seal rubber (23) in which a concave groove (23a) constituting a cooling water outlet is formed at the downstream end of the downstream double pipe portion To provide a cooling water outlet that allows the cooling water passage to communicate with the exhaust passage while the passage cross-sectional area is reduced. A cooling structure for an exhaust device for a watercraft, wherein the rubber hose (15) is connected so as to cover the cooling water outlet (23a) . The cooling structure for an exhaust device for a watercraft according to claim 1, wherein the downstream double pipe portion of the exhaust pipe member (14) is inclined so as to gradually extend downward toward the downstream side. The cooling water outlet (23a) communicating the double pipe portion on the side and the exhaust passage is disposed on the left and right sides when viewed from the upstream side of the exhaust passage, and the rubber hose (15) is connected to the exhaust pipe member (14 cooling structure for water travel marine exhaust system is characterized in that extended toward the substantially horizontal direction is bent from the connection portion of the). 2. The cooling structure for an exhaust device for a watercraft according to claim 1 , wherein the temperature of the exhaust passage wall surface in the single pipe portion between the upstream double pipe portion and the downstream double pipe portion in the exhaust pipe member (14) is set. A cooling structure for an exhaust device for a watercraft, which is provided with a temperature sensor (30) for detecting the temperature.

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