JP4627504B2 - Intake structure for small vessels - Google Patents

Description

  The present invention relates to an intake structure for a small vessel in which a supercharger is provided behind an engine, and the supercharger communicates with an intake passage via an intercooler.

In the intake structure of a small vessel, a turbocharger (supercharger) is provided at the rear of the engine, an intercooler is provided at the side of the engine, and this intercooler is connected to the turbocharger via a communication pipe. (For example, refer to Patent Document 1).
JP 2004-116478 A

According to the intake structure of the small vessel, the air sucked into the air cleaner is guided to the turbocharger. The air guided to the turbocharger is guided to the intercooler via the communication pipe.
Thereafter, the air led to the intercooler is led to the air box via the throttle valve, and the air led to the air box is led into the cylinder.

By the way, the conventional air intake structure of a small vessel is provided with an air box above the intercooler. Intercoolers and air boxes are relatively large shaped members.
In addition, it is necessary to secure a space for arranging a cooling water hose for water cooling and a space for routing a control harness around the intercooler.
For this reason, in order to obtain the capacity | capacitance of an intercooler, it was difficult to ensure the shape of an intercooler comparatively large.

Furthermore, in the conventional small ship intake structure, the air outlet of the turbocharger faces upward and the air inlet of the intercooler faces rearward.
For this reason, in order to connect the air outlet of the turbocharger and the air inlet of the intercooler with a communication pipe, it is necessary to bend the communication pipe into a complicated shape, which hinders cost reduction.

  It is an object of the present invention to provide an intake structure for a small vessel that can easily secure the capacity of the intercooler and that can communicate the intercooler with a supercharger through a communication portion having a simple shape.

In the invention according to claim 1, the hull is provided with an engine so that the plurality of cylinders are arranged in the front-rear direction of the hull so that one of the left and right sides of the plurality of cylinders communicates with each cylinder. An intake passage is disposed, an exhaust passage communicating with each cylinder is disposed on the other side, a supercharger is provided behind the engine, and the supercharger is communicated with the intake passage via an intercooler. In the intake structure of a small vessel, the intercooler is provided horizontally above the supercharger behind the engine, and the air inlet of the intercooler is disposed on the same axis as the air outlet of the supercharger so as to communicate therewith. It is, in front of the intercooler, and the one side, is provided so as to extend in the longitudinal direction of the dispensing passage hull that communicates with the intake passage, the rear end of the distribution channel An air outlet of the intercooler and is characterized in that it communicates arranged to face coaxially.

  The invention according to claim 2 is characterized in that the supercharger is a turbocharger connected to the exhaust passage and driven by engine exhaust gas guided from the exhaust passage.

  The invention according to claim 3 is characterized in that a rear end portion of the distribution passage and the intercooler are communicated with each other through a distribution passage communication portion, and a throttle valve is provided at the distribution passage communication portion.

  The invention according to claim 4 is characterized in that the intercooler is disposed close to the one side, and the turbocharger is disposed close to the other side.

Here, the distribution passage is disposed on one side of the plurality of cylinders, and the exhaust passage is disposed on the other side of the plurality of cylinders.
Accordingly, in claim 4, the intercooler is disposed close to one side of the plurality of cylinders, and the turbocharger is disposed close to the other side of the plurality of cylinders.

In the invention according to claim 1, by providing the intercooler behind the engine, the intercooler can be separated from the intake passage and the distribution passage having a relatively large shape. In addition, it is easy to ensure a relatively large space behind the engine.
Therefore, the space for arranging the cooling water hose for water cooling and the space for arranging the harness for control can be easily secured around the intercooler.
Thereby, it becomes easy to make the shape of an intercooler comparatively large, and there exists an advantage that the capacity | capacitance of an intercooler can be ensured easily.

Furthermore, by providing the intercooler behind the engine, the intercooler can be disposed in the vicinity of the supercharger.
Thereby, there exists an advantage that the intercooler communication part which connects an intercooler to a supercharger can be made into a simple structure.

In addition, in the invention according to claim 1, the distribution passage is arranged to extend in front of the intercooler and in the front-rear direction of the hull. Therefore, the rear end portion of the distribution passage can face the intercooler.
By connecting the intercooler to the rear end portion, there is an advantage that the distribution passage communication portion that communicates the intercooler to the rear end portion can be simplified.

In the invention according to claim 2, the turbocharger driven by the exhaust gas of the engine guided from the exhaust passage is used as the supercharger provided behind the engine.
Here, the exhaust gas of the engine is usually guided to the rear of the engine by an exhaust structure (exhaust system) extending from the exhaust passage to the rear of the hull.

Therefore, by arranging the turbocharger behind the engine, it becomes possible to make the turbocharger communicate with the exhaust passage using the exhaust structure.
Thereby, there exists an advantage that the communication part which connects a turbocharger to an exhaust passage can be made into a simple structure.

In the invention according to claim 3, the rear end portion of the distribution passage and the intercooler are communicated with each other through the distribution passage communication portion, and the throttle valve is provided in the distribution passage communication portion.
Here, the intercooler is provided behind the engine, and the distribution passage is provided so as to extend in the front-rear direction of the hull. Therefore, the rear end portion of the distribution passage is located on the rear side of the engine. Since the rear end portion on the rear side of the engine and the intercooler provided at the rear of the engine communicate with each other through the distribution passage communication portion, the distribution passage communication portion is located behind the engine.

Since the throttle valve is provided in the distribution passage communication portion, the throttle valve can be disposed on the rear side of the engine.
Since a relatively large space is secured on the rear side of the engine, the throttle valve can face the wide space.
As a result, there is an advantage that maintenance and inspection of the throttle valve can be performed using a relatively wide space on the rear side of the engine, thereby improving maintainability.

In the invention which concerns on Claim 4, an intercooler can be closely approached to a distribution channel | path by arrange | positioning an intercooler near one side of a some cylinder.
Therefore, the distribution passage communication portion that communicates the intercooler with the distribution passage can be kept short.

Furthermore, the turbocharger can be brought close to the exhaust passage by arranging the turbocharger close to the other side of the plurality of cylinders.
Therefore, the communication part which connects a turbocharger to an exhaust passage can be suppressed short.

  In this way, the distribution passage communication portion that communicates the intercooler with the distribution passage and the communication portion that communicates the turbocharger with the exhaust passage can be kept short, so that the intake structure of a small vessel can be combined into a compact layout. There are advantages.

  The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. “Front”, “rear”, “left”, and “right” indicate the front as Fr, the rear as Rr, the left as L, and the right as R according to the direction seen from the driver.

FIG. 1 is a side view showing a small vessel according to the present invention.
The small vessel 10 includes a fuel tank 12 at a front portion 11 a of a hull 11, an engine 13 at the rear of the fuel tank 12, a pump chamber 14 at the rear of the engine 13, and a water jet in the pump chamber 14. A pump 15, a drive shaft 17 that connects the water jet pump 15 to the output shaft 16 of the engine 13, an intake structure (an intake structure of a small ship) 20 that supplies air to the engine 13, and exhaust gas from the engine 13 The water jet propulsion boat is provided with an exhaust structure 21 for discharging the fuel, a steering handle 22 above the fuel tank 12, and a seat 23 behind the steering handle 22.

  The hull 11 is obtained by covering the hull 25 constituting the lower part of the hull 11 with the deck 26 constituting the upper part of the hull 11 and joining the deck 26 to the hull 25.

According to the small vessel 10, the impeller 18 is rotated by driving the engine 13 and rotating the drive shaft 17. The impeller 18 is built in the water jet pump 15.
By rotating the impeller 18, water sucked from the suction port 19 at the bottom of the boat is jetted from the steering nozzle (steering nozzle) 24 to the rear of the hull 11 through the water jet pump 15.
Thereby, the small vessel 10 is propelled (sliding) in the forward state.

On the other hand, when the small boat 10 is moved backward, the reverse bucket 27 above the steering nozzle 24 is moved to the reverse position behind the steering nozzle 24.
As a result, the water sprayed backward from the steering nozzle 24 is guided to the front of the hull 11 by the reverse bucket 27, and the small vessel 10 is moved backward by the guided water spray.

FIG. 2 is a perspective view showing the inside of a small vessel according to the present invention.
In the engine 13, a plurality of cylinders 28 are arranged in the front-rear direction of the hull 11, and left and right attachment portions are attached to the hull 25 with bolts 29. That is, the engine 13 is attached to the hull 11 in a vertically installed state.

An output shaft 16 projects from the lower rear end of the engine 13 toward the rear of the hull 11. A drive shaft 17 is connected to the output shaft 16 via a connection coupler 31.
The drive shaft 17 is rotatably supported by a bearing portion 32, and a rear end portion is connected to the water jet pump 15 (see FIG. 1).
The flange portion 33 of the bearing portion 32 is attached to the hull 25 with bolts and nuts.

By installing the engine 13 vertically with respect to the hull 11, the intake passage 35 is disposed on the left side (one side) of the plurality of cylinders 28. A passage 36 is disposed.
The intake passage 35 constitutes an intake manifold, for example. The exhaust passage 36 constitutes, for example, an exhaust manifold.

The intake passage 35 is a member constituting a part of the intake structure 20 and communicates with the cylinders 28.
The exhaust passage 36 is a member constituting a part of the exhaust structure 21 and communicates with the cylinders 28.

The intake structure 20 includes an air cleaner 41, a turbocharger (supercharger) 42, an intercooler 43, a distribution passage 44, an intake passage 35, and the like.
The air cleaner 41 is communicated with the turbocharger 42 via an air introduction pipe 46. The turbocharger 42 communicates with the intercooler 43, and the intercooler 43 communicates with the distribution passage 44 via the distribution passage communication portion 48. The distribution passage 44 communicates with the intake port of the intake passage 35.

The exhaust structure 21 includes an exhaust passage 36, a first exhaust pipe 51, a second exhaust pipe 52, an exhaust body 53, a water muffler 54, an exhaust hose 55, and the like.
A first exhaust pipe 51 is provided from the rear end of the exhaust passage 36 toward the rear of the hull. The rear end portion 51 a of the first exhaust pipe 51 communicates with the second exhaust pipe 52 and also communicates with the turbocharger 42.

  An exhaust body 53 communicates with the second exhaust pipe 52, and a water muffler 54 communicates with the exhaust body 53. An exhaust hose 55 communicates with the water muffler 54, and an exhaust port 55a of the exhaust hose 55 faces the pump chamber 14 (see FIG. 1).

FIG. 3 is a perspective view showing an intake structure of a small boat according to the present invention, and FIG. 4 is an exploded perspective view showing an intake structure of the small boat according to the present invention.
The air cleaner 41 is provided on the front left side of the engine 13 and communicates with the turbocharger 42 via an air introduction pipe 46.
The turbocharger 42 is provided behind the engine 13 and above the output shaft 16. Further, the turbocharger 42 is disposed horizontally so as to approach the right side of the plurality of cylinders 28 (that is, the right side of the engine 13).
Horizontal installation means a state in which the hull 11 is arranged in the width direction.

By setting the turbocharger 42 horizontally, the turbine casing 61 is disposed on the right side 63a side of the cylinder block 63, and the compressor casing 62 is disposed behind the cylinders 28 (ie, substantially in the center of the engine 13). The
In the compressor casing 62, an air inlet 65 for introducing air is provided leftward, and an air outlet 66 for sending out air is provided upward.
The air inlet 65 communicates with the air cleaner 41 via the air introduction pipe 46.

By arranging the turbine casing 61 on the right side 63a side of the cylinder block 63, the end surface 61a of the turbine casing 61 can be moved to the right side 63a.
The end surface 61 a of the turbine casing 61 that is brought to the right side 63 a is connected to the rear end 51 a of the first exhaust pipe 51. Therefore, the turbine casing 61 is communicated with the first exhaust pipe 51.
In the turbocharger 42, the turbine casing 61 is communicated with the exhaust passage 36 via the first exhaust pipe 51.
That is, the turbocharger 42 is a supercharger that is driven by the exhaust gas of the engine 13 guided from the exhaust passage 36.

By using the turbocharger 42 as a supercharger provided behind the engine, the turbocharger 42 can be communicated with the exhaust passage 36 using the first exhaust pipe 51. The first exhaust pipe 51 is a member that constitutes a part of the exhaust structure 21.
Thus, since the turbocharger 42 can be communicated with the exhaust passage 36 by using a member that constitutes a part of the exhaust structure 21, the communication portion that communicates the turbocharger 42 with the exhaust passage 36 has a simple configuration. It can be.

An intercooler 43 is provided above the turbocharger 42 and behind the engine 13. The intercooler 43 is a member formed in a box shape, and is disposed side by side toward the left side of the plurality of cylinders 28 (that is, the left side of the engine 13).
Therefore, the left end portion 43a of the intercooler 43 is arranged on the left side portion 63b side of the cylinder block 63, and the right end portion 43b of the intercooler 43 is arranged behind the cylinders 28 (that is, substantially in the center of the engine 13).

In the intercooler 43, an air inlet 67 for introducing air is provided downward on the front wall 43c on the right end 43b side, and an air outlet 68 for delivering air is provided forward on the front wall 43c on the left end 43a side. ing.
Further, the intercooler 43 is provided with a water inlet 71 for introducing cooling water at the left end 43a, and a water outlet 72 for sending out the cooled water at the right end 43b.

The right end 43b of the intercooler 43 is disposed behind the cylinders 28 (that is, approximately the center of the engine 13), so that the air inlet 67 is positioned above the air outlet 66 of the compressor casing 62.
Here, the air inlet 67 of the intercooler 43 is disposed downward, and the air outlet 66 of the compressor casing 62 is disposed upward.
Therefore, the air inlet 67 of the intercooler 43 can be disposed on the coaxial line 69 so as to face the air outlet 66 at a position near the air outlet 66 of the compressor casing 62.

Thereby, the air inlet 67 of the intercooler 43 and the air outlet 66 of the compressor casing 62 can be communicated with each other by a relatively short and substantially straight intercooler communication hose (intercooler communication portion) 74.
The intercooler communication hose 74 has an upper end 74 a fastened to the air inlet 67 by a fastening band 76 and a lower end 74 b fastened to the air outlet 66 by a fastening band 76.
Thereby, the intercooler 43 is communicated with the turbocharger 42.

A distribution passage 44 is provided in front of the left end portion 43 a of the intercooler 43 and on the intake port side of the intake passage 35.
The distribution passage 44 is provided so as to extend in the front-rear direction of the hull 11 and communicates with the intake port of the intake passage 35.
Therefore, the rear end portion 44 a of the distribution passage 44 can be disposed substantially coaxially so as to face the air outlet 68 at a position near the air outlet 68 of the intercooler 43.

As a result, the rear end portion 44a of the distribution passage 44 and the air outlet 68 of the intercooler 43 can communicate with each other through a relatively short and substantially straight distribution passage communication portion 48.
The distribution passage communication portion 48 communicates with the intake port of the intake passage 35 through the distribution passage 44. Therefore, the intake passage 35 communicates with the turbocharger 42 via the intercooler 43, the distribution passage communication portion 48, and the like.

As described above, the intercooler 43 can be brought closer to the distribution passage 44 by arranging the intercooler 43 close to the left side of the plurality of cylinders 28.
Therefore, the distribution passage communication portion 48 that communicates the intercooler 43 with the distribution passage 44 can be kept short.

Furthermore, the turbocharger 42 can be brought close to the exhaust passage 36 by arranging the turbocharger 42 close to the right side of the plurality of cylinders 28.
Therefore, the first exhaust pipe (that is, the communication portion) 51 that communicates the turbocharger 42 with the exhaust passage 36 can be kept short.

  Thus, the intercooler 43 is small in size because the distribution passage communication portion 48 communicating with the distribution passage 44 and the first exhaust pipe (that is, the communication portion) 51 communicating the turbocharger 42 with the exhaust passage 36 can be kept short. The ship intake structure 20 can be combined into a compact layout.

The distribution passage communication portion 48 includes a valve storage passage 78 extending rearward from the rear end portion 44 a of the distribution passage 44, and a communication extending rearward from the rear end portion 78 a of the valve storage passage 78 to the air outlet 68 of the intercooler 43. A hose 79.
The valve storage passage 78 stores therein a throttle valve 81 and an air inlet 82 for introducing air into the rear end portion 78a.

A valve shaft 83 of the throttle valve 81 protrudes from a side wall portion of the valve housing passage 78, and a lever 84 is connected to the valve shaft 83. The distal end portion of the operation cable 85 is coupled to the distal end portion of the lever 84, and the proximal end portion of the operation cable 85 is coupled to a throttle lever (not shown).
The throttle lever is provided on the steering handle 22 (see FIG. 1). Therefore, the opening degree of the throttle valve 81 can be adjusted by operating the throttle lever with the hand holding the steering handle 22.

By storing the throttle valve 81 inside the valve storage channel 78, the throttle valve 81 can be disposed on the rear side of the engine 13.
Since the rear side of the engine 13 has a relatively wide space, the throttle valve 81 can face the wide space.
As a result, the throttle valve 81 can be maintained and inspected using a relatively large space on the rear side of the engine 13.

The air inlet 82 of the valve housing channel 78 can be disposed on the coaxial line 73 so as to face the air outlet 68 at a position near the air outlet 68 of the intercooler 43.
Thereby, the air inlet 82 of the valve storage passage 78 and the air outlet 68 of the intercooler 43 can be communicated with each other by a relatively short and substantially straight communication hose 79.
The communication hose 79 has a rear end 79 a fastened to the air outlet 68 by a fastening band 87 and a front end 79 b fastened to the air inlet 82 by a fastening band 87.

  As described above, according to the intake structure 20 of the small boat, the intercooler 43 can be separated from the relatively large intake passage 35 and distribution passage 44 by providing the intercooler 43 behind the engine 13. Become. In addition, it is easy to ensure a relatively large space behind the engine 13.

Therefore, a space for disposing a cooling water hose for water cooling and a space for routing a harness for control can be easily secured around the intercooler 43.
Thereby, it becomes easy to make the shape of the intercooler 43 relatively large, and the capacity of the intercooler 43 can be easily secured.

Furthermore, by providing the intercooler 43 behind the engine 13, the intercooler 43 can be disposed in the vicinity of the turbocharger 42.
Thereby, the intercooler communication hose 74 that allows the intercooler 43 to communicate with the turbocharger 42 can have a simple configuration.

In addition, the distribution passage 44 is disposed in front of the intercooler 43 and extends in the front-rear direction of the hull 11. Therefore, the rear end portion 44 a of the distribution passage 44 can face the intercooler 43.
By connecting the intercooler 43 to the rear end portion 44a, the distribution passage communication portion 48 that allows the intercooler 43 to communicate with the rear end portion 44a can be simplified.

Next, an example in which air is guided to a cylinder by an intake structure of a small ship will be described with reference to FIG.
FIG. 5 is a view for explaining an example in which air is sucked into a cylinder by the intake structure of a small vessel according to the present invention.
Exhaust gas is led from the cylinders 28 to the exhaust passage 36, and the exhaust gas led into the exhaust passage 36 is led to the first exhaust pipe 51 as indicated by an arrow A.
Of the exhaust gas guided to the first exhaust pipe 51, most of the exhaust gas is guided as shown by arrow B, and exhausted through the second exhaust pipe 52, the exhaust body 53, the water muffler 54, and the exhaust hose 55 shown in FIG. Is done.

On the other hand, of the exhaust gas guided to the first exhaust pipe 51, the remaining exhaust gas is guided to the turbine casing 61 as indicated by an arrow C. A turbine impeller (not shown) is rotated by the exhaust gas guided to the turbine casing 61.
As the turbine impeller rotates, a compressor impeller (not shown) in the compressor casing 62 rotates.

Simultaneously with the rotation of the compressor impeller, air is sucked into the air cleaner 41 as indicated by an arrow D. The air sucked into the air cleaner 41 is guided through the air introduction pipe 46 as indicated by arrows E and F.
The air guided through the air introduction pipe 46 is guided to the compressor casing 62 of the turbocharger 42 as indicated by an arrow G.

Here, as described above, since the compressor impeller (not shown) in the compressor casing 62 is rotating, the air introduced into the compressor casing 62 is compressed and the arrow H from the compressor casing 62 is compressed. It is sent out like this.
The air sent out from the compressor casing 62 is led to the air inlet 67 of the intercooler 43 through the intercooler communication hose 74 as shown by the arrow I, and is led into the intercooler 43 from the air inlet 67.

  Cooling water is introduced into the intercooler 43 from the water inlet 71. The guided cooling water cools the air guided from the compressor casing 62 into the intercooler 43 and is sent out from the water outlet 72 to the outside.

The air cooled in the intercooler 43 is guided to the air outlet 68 and is guided from the air outlet 68 to the communication hose 79 as indicated by an arrow J.
The air guided to the communication hose 79 is guided from the communication hose 79 to the valve storage passage 78 as indicated by an arrow K.

The air guided to the valve housing channel 78 is guided to the distribution passage 44 as indicated by an arrow L through the throttle valve 81.
The air guided to the distribution passage 44 is guided to the intake passage 35 as indicated by an arrow M and is supplied from the intake passage 35 into each cylinder 28.

  In the above-described embodiment, the example in which the intake passage 35 and the exhaust passage 36 are respectively disposed on the left and right sides with one side of the plurality of cylinders 28 being the left side and the other side the right side has been described. It is also possible to arrange the exhaust passage 36 on the left side and the intake passage 35 on the right side, with one side of the plurality of cylinders 28 being the right side and the other side being the left side.

  Moreover, in the said embodiment, although the turbocharger 42 driven using exhaust gas as a supercharger was illustrated, it is not restricted to this, For example, the machine driven using rotation of the crankshaft of the engine 13 Other superchargers such as a driven supercharger can also be used.

  Furthermore, in the said embodiment, although the communication hose 74 was illustrated as an intercooler communication part, it is not restricted to this, For example, it is also possible to use the communication pipe made from aluminum.

  In the above embodiment, the example in which the rear end portion 78a of the valve housing flow path 78 and the air outlet 68 of the intercooler 43 are communicated with each other by the communication hose 79 is described. However, the present invention is not limited to this. It is also possible to use a pipe.

  The present invention is suitable for application to a small vessel having an intake structure in which a supercharger is provided behind the engine and an intercooler is communicated with the supercharger.

It is a side view which shows the small ship which concerns on this invention. It is a perspective view which shows the inside of the small ship which concerns on this invention. It is a perspective view which shows the intake structure of the small ship which concerns on this invention. It is a disassembled perspective view which shows the intake structure of the small ship which concerns on this invention. It is a figure explaining the example which suck | inhales air in a cylinder with the intake structure of the small ship which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Small vessel, 11 ... Boat body, 13 ... Engine, 20 ... Intake structure of small vessel, 28 ... Cylinder, 35 ... Intake passage, 36 ... Exhaust passage, 42 ... Turbocharger (supercharger), 43 ... Intercooler, 44 ... Distributing passage, 44a ... Rear end portion of distributing passage , 66 ... Air outlet of turbocharger (compressor compartment), 67 ... Air inlet of intercooler, 68 ... Air outlet of intercooler, 69, 73 ... Coaxial line , 81 ... Throttle valve.

Claims (4)

By providing an engine in the hull so that a plurality of cylinders are arranged side by side in the longitudinal direction of the hull, an intake passage communicating with each cylinder is arranged on one side of the left and right sides of the plurality of cylinders, In the intake structure of a small vessel, an exhaust passage communicating with each cylinder is disposed on the other side, a supercharger is provided behind the engine, and the supercharger is communicated with the intake passage via an intercooler.
The intercooler is provided horizontally above the supercharger at the rear of the engine, and the air inlet of the intercooler is disposed on the same axis as the air outlet of the supercharger and communicated therewith,
In front of the intercooler, and the one side, it is provided so as to extend in the longitudinal direction of the dispensing passage hull that communicates with the intake passage,
An intake structure for a small vessel, characterized in that a rear end portion of the distribution passage and an air outlet of the intercooler are arranged to communicate with each other on a coaxial line .   2. The intake structure for a small vessel according to claim 1, wherein the supercharger is a turbocharger that is connected to the exhaust passage and is driven by engine exhaust gas guided from the exhaust passage.   The intake structure for a small vessel according to claim 1, wherein a rear end portion of the distribution passage and the intercooler are communicated with each other through a distribution passage communication portion, and a throttle valve is provided at the distribution passage communication portion.   The intake structure for a small vessel according to claim 2, wherein the intercooler is arranged close to the one side, and the turbocharger is arranged close to the other side.

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