1. Field of the Invention
The present invention relates to a structure of an engine cover that covers an upper part of an engine.
2. Background Art
Conventionally, there is a well-known type of engine whose cylinder head is surrounded by devices such as a muffler, a fuel tank and an air cleaner. For example, Japanese Patent Application Publication No. Hei 8-232654 discloses a technique to send cooling air from a fan provided on one side of a cylinder block to the opposite side of the cylinder block, thereby improving cooling efficiency of the engine.
However, according to the above conventional art, sound insulation is not taken into consideration and the engine is provided with only a structure for guiding cooling air wherein the cylinder head and a cylinder are arranged to be surrounded by an air exhaust flange.
On the other hand, attaching of a cover on an engine is an ordinary technique for preventing emission or transmission of vibration, noise, etc. caused by driving an engine. In this case, the cover is arranged to cover an overall body of the engine so that the engine must have a large housing. Furthermore, attachment of the cover must be a time and labor consuming task, thereby making maintenance work harder. Furthermore, for attaching a cover onto a general purpose engine, a different cover is required corresponding to a type of working vehicle to which the engine is mounted.
According to the present invention, an engine whose cylinder head is covered at three of front, rear, right and left sides thereof by a fuel tank, an air cleaner and a muffler, respectively, comprises a cover which covers the remaining one side and/or a top side of the cylinder head. Due to this structure, the cylinder head can be protected by the cover, and noise caused by the cylinder head can be reduced. Furthermore, the cover can send cooling air from a fan provided on one side of a cylinder block via the cylinder head to an exhaust pipe disposed on the opposite side of the cylinder block, which is an exposed side of the cylinder head where no device such as a muffler is disposed. Therefore, the cylinder head and the exhaust pipe can be cooled.
According to the invention, the cover is formed to have an approximate inverse L shape in a section view so as to cover an exposed side of the cylinder head and the top of the cylinder head. Due to this structure, sound insulation is improved to reduce noise caused by the cylinder head. Furthermore, cooling air from a fan provided on one side of the cylinder block can be guided to cool the cylinder head as well as a bonnet cover, etc. disposed over the cylinder head, thereby improving cooling efficiency. Still further, the cover covers the exhaust pipe disposed on the exposed side of the cylinder head, thereby preventing users from accidentally touching the exhaust pipe. In addition, the cover can be used as a means for covering a base portion of a muffler (a joint between the muffler and the exhaust pipe).
According to the invention, the cover comprises a side cover to cover the exposed side of the cylinder head and a top cover to cover the top side of the cylinder head. Due to this structure, the cover can be separated into the top cover and the side cover, thereby facilitating attachment of the cover onto the engine. Furthermore, the top cover or the side cover can be removed individually so that parts desired to be detached from the engine can be easily detached, thereby enhancing ease of maintenance.
According to the invention, the side cover and the top cover are integrally formed. Due to this structure, attachment work of the cover onto the engine is made easier.
According to the invention, the side cover is bent corresponding to a shape of an exhaust pipe disposed on a side surface of the cylinder head. Due to this structure, the side cover covers the exhaust pipe, thereby preventing users from accidentally touching the exhaust pipe.
According to the invention, the side cover is disposed on a side of the cylinder head opposite to the air cleaner. Due to this structure, the cylinder head is covered at the front, rear, left and right sides thereof by the muffler, the fuel tank, the air cleaner and the side cover, and also covered by the top cover disposed thereabove, thereby improving sound insulation to reduce noise caused by the cylinder head. Furthermore, the side cover covers an exposed portion of the cylinder, thereby preventing users from accidentally touching the cylinder head, and also improving appearance of the engine.
According to the invention, a fan is disposed on one side of a cylinder block beneath the cylinder head, and the side cover is extended to cover another side of the cylinder block opposite to the fan. Due to this structure, the side cover functions as a guiding plate to guide cooling air from the fan to an outer surface of the cylinder block opposite to the fan. Therefore, the whole body of the cylinder head is cooled down, and further the surface of the cylinder block opposite to the fan is also cooled down.
According to the invention, the side cover has a notched upper edge portion fixed on a side surface of the top cover. Due to this structure, an operating portion of a decompressor provided on the engine can be disposed at the notched portion without projecting to the outside of the side cover. Therefore, the operating portion of the decompressor can be operated without having to detach the cover from the engine, thereby keeping good appearance of the engine. Furthermore, the top cover and the side cover can be joined to form an approximate inverse L shape, thereby improving appearance of the engine.
According to the invention, the side cover is formed on a side surface thereof with an opening. Due to this structure, cooling air can be sufficiently drawn out from the opening, thereby improving cooling efficiency. In addition, weight of the side cover can be reduced by the area of the opening.
According to the invention, the side cover has a lower edge portion whose at least one side is perpendicularly bent to form a projection inserted into a slit formed in a main body of the engine so as to attach the side cover to the main body. Due to this structure, the side cover can easily be fixedly positioned with respect to the main body of the engine. Furthermore, a fixed portion can be easily formed in the side cover.
According to the invention, the top cover is formed on a top surface thereof with an attachment hole for attachment of the top cover onto the engine, periphery of the attachment hole being funnel-formed and the attachment hole being formed with a slit on an inner side surface thereof. Due to this structure, water is drained through the slit, thereby preventing water from ponding on the top surface of the top cover when, for example, rainwater falls on the top surface of the top cover. Furthermore, water draining structure can be easily formed on the top cover.
According to the invention, the top cover is formed on a top surface thereof with a hole for inserting a lifting member and a hole for feeding startup assisting material. Due to this structure, a lifting member for lifting up the engine can be easily attached to the cylinder head without having to detach the top cover from the engine. Therefore, the engine can be easily lifted up only by the lifting member without any additional member such as a guide member attached on the main body of the engine. And, also due to this structure, startup assisting material can be fed from the latter hole without having to detach the top cover from the main body of the engine.
According to the invention, an operating portion of a decompressor is disposed below a top surface of the top cover. Due to this structure, the operating portion of the decompressor does not jut out above the top surface of the top cover, thereby keeping good appearance of the engine.
According to the invention, the operating portion of the decompressor is provided as a decompressor lever, and the side cover is formed thereon with a hole for inserting a control shaft of the decompressor lever, the decompressor lever being projected to the outside of the side cover. Due to this structure, the decompressor can be controlled with the decompressor lever in a state where the cover is attached on the engine.
According to the invention, a cooling air guide for guiding cooling air to a space between a bonnet cover and the top cover disposed over the cylinder head is formed in a cylinder head side of a body of the air cleaner. Due to this structure, cooling air from a fan can be guided and divided by the cooling air guide to cool the bonnet cover and a fuel injection nozzle as well as the cylinder head. Furthermore, the cooling air guide can be easily formed by casting, etc.
According to the invention, the cooling air guide is integrally formed on a partition wall formed in the cylinder head side of the body of the air cleaner. Due to this structure, the cooling air guide can be produced cost-effectively because it requires neither special additional part attached onto the body of the air cleaner nor processing of the body.
Referring to
An engine 1 comprises a cylinder block 2 in an upper part thereof and a crankcase 3 in a lower part thereof. In the middle of cylinder block 2 is formed a vertically-directed cylinder 2a with a piston 4. Piston 4 is connected via a connection rod 6 to a crankshaft 5 which is pivotally supported by crankcase 3.
A balance weight, a governor 11, etc. are disposed within crankcase 3 beneath cylinder block 2. A cam shaft 13, a fuel injection pump 12, etc. are disposed above governor 11. Fuel injection pump 12 draws fuel from a fuel tank 10 by pushing and pulling a plunger of fuel injection pump 12 with a pump-driving cam 14 provided on cam shaft 13 at the center thereof in the fore-and-aft direction, and supplies a certain amount of fuel to a fuel injection nozzle 15 via a high-pressure pipe 19 at a certain timing. The amount of fuel injection from nozzle 15 can be controlled by turning a control lever 16 of fuel injection pump 12 to change a stroke of the plunger.
On cylinder block 2 is disposed a cylinder head 7, inside of which a suction valve 31, an exhaust valve 32 and fuel injection nozzle 15 are disposed. A bonnet cover 8 is provided on cylinder head 7 forming a rock arm chamber 8a, within which upper end portions of respective suction valve 31 and exhaust valve 32, upper end portions of respective rock arms 27 and 28 and a pushrod 25, etc. are disposed. Three out of four sides (front, rear left and right sides) of cylinder head 7 and bonnet cover 8 are surrounded by a muffler 9, fuel tank 10 and an air cleaner 20. According to the present embodiment, muffler 9, fuel tank 10 and air cleaner 20 are respectively disposed in the right, left and rear sides of cylinder head 7. The remaining side (front side) and an upper side of cylinder head 7 are respectively covered with a side cover 51 and a top cover 55 of a cover 50.
A fan 35 is disposed on one side (rear side) of cylinder block 2 under air cleaner 20. Fan 35 consists of a flywheel 35a which is fixed on one end of crankshaft 5 and integrally formed with fins 35b on a peripheral portion of an outer side surface thereof. Fan 35 is covered by a fan case 36. By rotating fan 35, air is drawn into fan case 36 from outside and then sent toward cylinder block 2, cylinder head 7, etc. to cool them. The air is also supplied to air cleaner 20.
As shown in
Valve rod 31b (32b) is slidably inserted into cylinder head 7 and projecting upward to the bonnet cover 8 side. A top end of valve rod 31b (32b) is contacted with a rock arm 27 (28). Inside rock arm chamber 8a, a spring 33 (33) is put on valve rod 31b (32b) so that valve head 31a (31b) is biased to slide upward and shut suction valve 31 (exhaust valve 32).
Fuel injection nozzle 15 is disposed between suction valve 31 and exhaust valve 32. Fuel injection nozzle 15 is inserted into cylinder head 7 and projects downward with a tip thereof (an injecting portion) positioned above a center of cylinder 2a. Fuel injection nozzle 15 is connected at the other end thereof to high pressure pipe 19 extending from fuel injection pump 12 so as to inject fuel supplied from fuel injection pump 12 into cylinder 2a.
Cylinder head 7 and bonnet cover 8 are pierced at one ends thereof by a vertical connecting hole 37. Connecting hole 37 is connected to suction port 7a. Startup-assisting material is injected into cylinder 2a from connecting hole 37 through suction port 7a for assisting smooth startup of an engine under the condition of low temperature. When injecting operation is not performed, connecting hole 37 is normally plugged with a cap 38 to prevent an extraneous substance from entering into cylinder 2a and mixing with internal air.
A decompressor 39 is provided on bonnet cover 8. Decompressor 39 forcedly opens exhaust valve 32 or suction valve 31 at engine startup in order to decrease a compressive force inside cylinder 2a and reduce a cranking force, thereby enhancing starting performance of the engine. (In this embodiment, decompressor 39 is typically provided on exhaust valve 32.) Decompressor 39 comprises a control shaft 39a pivotally supported by bonnet cover 8 and a decompressor lever 39b attached to control shaft 39a as an operating portion.
Control shaft 39a of decompressor 39 is disposed horizontally in the fore-and-aft direction, and turnably supported by bonnet cover 8. Decompressor lever 39b is integrally fixed on one end of control shaft 39a projecting forward to the outside. The other end of control shaft 39a projecting into the inside of rock arm chamber 8a is formed with a notched semicylindrical contacting portion 39c. Contacting portion 39c is arranged so that it can contact with rock arm 28. Therefore, as control shaft 39a is turned by decompressor lever 39b, contacting portion 39c comes to contact with rock arm 28 and push it. Then, rock arm 28 pushes exhaust valve 32 and slides it downward against the biased force of the spring, thereby opening exhaust valve 32. Therefore, when piston 4 moves upward, air inside cylinder 2a is not compressed as it is exhausted from exhaust valve 32. As a result, crankshaft 5 can be rotated with a little driving force.
As shown in
A suction opening 20a is formed at a bottom part of air cleaner 20 for sucking air directly from outside or from fan case 36. Suction opening 20a is formed by a cutaway part in a bottom periphery of cover 41 when cover 41 is fixed on body 40. Suction opening 20a opens downward so as to suck air into air cleaner 20 from outside. Further, a suction hole 40j, which serves as a flow path for air, is formed at a central part of body 40. Suction hole 40j and suction port 7a of cylinder head 7 are connected with each other.
As shown in
Furthermore, partition wall 40b and partition wall 40c are integrally formed at respective middle parts thereof with respective upwardly projecting cooling air guides 40e and 40f When body 40 is attached to cylinder head 7, cooling air guides 40e and 40f are positioned over a top surface of cylinder head 7 to respectively form openings 48 and 49 so that a space formed between partition walls 40b, 40c and 40d and cylinder head 7 is fluidly connected to a space formed between a later-discussed top cover 55 of cover 50 and cylinder head 7. Therefore, a part of cooling air flowing from fan 35 is guided by cooling air guides 40e and 40f of partition walls 40b and 40c so as not to be sent into cylinder head 7 but to be sent from openings 48 and 49 to a space between bonnet cover 8 and top cover 55 over cylinder head 7.
In this way, cooling air guides 40e and 40f, which serve as intakes of cooling air into the space between bonnet cover 9 and top cover 55 over cylinder head 7, are formed in the cylinder head 7 side of body 40 of air cleaner 20. Therefore, cooling air guides 40e and 40f can guide cooling air sent from fan 35 to bonnet cover 8 to cool it as well as cylinder head 7. Furthermore, cooling air guides 40e and 40f can be easily formed by casting, etc.
Furthermore, cooling air guides 40e and 40f are integrally formed on respective partition walls 40b and 40c which are formed in the cylinder head 7 side of body 40 of air cleaner 20 so that there is no need for any special additional part or for processing for body 40, thereby being produced cost-effectively.
Referring now to
Cover 50 comprises side cover 51 and top cover 55. While the upper part of the engine includes cylinder head 7 covered at three of front, rear, left and right sides thereof with muffler 9, fuel tank 10 and air cleaner 20, side cover 51 is arranged at the upper part of the engine so as to cover the remaining one side of cylinder head 7. Top cover 55 is arranged to cover the top of cylinder head 7 and bonnet cover 8. Cover 50, which covers both the remaining side and the top of cylinder head 7 in the present embodiment, may be arranged to cover at least one of the remaining side and the top of cylinder head 7. Cover 50 may be arranged to cover a wider area in addition to the exposed part of cylinder head 7.
In the present embodiment, side cover 51 is placed on the front side of cylinder head 7 which is not covered by any of muffler 9, fuel tank 10 and air cleaner 20. Side cover 51 is arranged to also cover exhaust pipe 34 disposed in front of cylinder head 7 and to cover the corresponding side of an upper part of cylinder block 2.
Side cover 51 is formed to have a hat-like shape and, in a rear view, to have an approximately trapezoidal shape. In other words, a vertically middle part of side cover 51, which serves as a part to cover exhaust pipe 34, projects forward to form a projecting portion 52 whose right and left sides are opened. Projecting portion 52 is formed in such a way that a vertical width thereof is increased in the direction from cylinder head 7 to muffler 9 so as to fit the shape of exhaust pipe 34.
Furthermore, side cover 51 is formed on a front surface thereof with plural openings 52a, 52b and 52c. In this embodiment, openings 52a, 52b and 52c are three vertically long openings formed on projecting portion 52 of side cover 51 at regular intervals. However, the number and the shape of openings are not to be specified. For example, more than three openings may be provided on projecting portion 52. Alternatively, instead of these openings, heat may be exhausted through right and left sides or top and bottom sides of side cover 51 without any openings provided. Any arrangement is possible of side cover 51 for exhausting heat only if exhaust pipe 34 is prevented from being directly contacted by side cover 51.
As shown in
On the other hand, a recess 54a, which is approximately V-shaped in a side view, is formed in an upper end portion 54 of side cover 51. Recess 54a has a closed arcuate end part 54c which is disposed on the axial line of control shaft 39a of decompressor 39 projecting forward from bonnet cover 8 when side cover 51 is attached on the main body of engine 1. Decompressor lever 39b on the outer end of control shaft 39a is positioned in recess 54a lower than the top of projecting part 52 of side cover 51, that is, in a receding part of side cover 51. Therefore, decompressor lever 39b does not protrude to the outside of side cover 51, thereby keeping good appearance of engine 1. Here, it should be noted that recess 54a may also be easily formed by punching, etc. The shape of recess 54a is not limited.
Furthermore, side cover 51 is provided at lower end portion 53 thereof with an attachment hole 53b for attachment of side cover 51 to the main body of the engine (cylinder block 2), and at upper end portion 54 thereof with plural attachment holes 54b and 54b for attachment of side cover 51 to top cover 55. A nut 68 is fixed on the inner side of upper end portion 54 of side cover 51 to correspond to attachment hole 54b.
Top cover 55 is disposed over cylinder head 7 to cover cylinder head 7, bonnet cover 8, etc. Top cover 55 is approximately rectangularly shaped, and a top surface 56 of top cover 55 is bent vertically downward at right, left and front sides thereof to form respective edge portions 57, 58 and 59.
Top cover 55 is provided on top surface 56 thereof with plural attachment holes 56a for attachment of top cover 55 to the main body of the engine. In this embodiment, four attachment holes 56a are provided, which are respectively arranged at four corners of top surface 56 of top cover 55.
As shown in
Furthermore, top cover 55 is formed on top surface 56 thereof with a lifting member insertion hole 56c and a startup assisting material injection hole 56d. As shown in
Startup assisting material injection hole 56d is positioned so that an opening thereof corresponds to the connecting hole 37 formed on bonnet cover 8 and cylinder head 7. Startup assisting material injection hole 56d has a width enough to pass cap 38 fitted into connecting hole 37 therethrough, so that cap 38 can be removed from startup assisting material injection hole 56d while keeping top cover 55 attached on the main body of engine 1. Therefore, startup assisting material can be injected into cylinder 2a from startup assisting material injection hole 56d via connecting hole 37 by opening connecting hole 37 without removing top cover 55 from the main body of engine 1.
Furthermore, of edge portions 57, 58 and 59 of top cover 55, front edge portion 59, which doesn't contact with any of muffler 9, fuel tank 10 and air cleaner 20, is formed thereon with plural attachment holes 59a and 59a for attachment of side cover 51 onto top cover 55. Further, edge portion 59 is formed in a lower end part thereof with a notched arcuate portion 59b that faces arcuate portion 54c of recess 54a formed on upper end portion 54 of side cover 51.
Referring to
Top cover 55 of cover 50 is attached on body 40 of air cleaner 20, cylinder head 7 and bonnet cover 8. Side cover 51 of cover 50 is attached on cylinder block 2 and top cover 55.
Body 40 of air cleaner 20 is formed in a cylinder head side thereof with projecting boss portions 40g and 40g for attachment of top cover 55. Each boss portion 40g is formed with a vertical bolt hole 40h. Of attachment holes 56a formed on top cover 55, attachment holes 56a and 56a disposed in the air cleaner 20 side of top cover 55 are arranged to correspond to bolt holes 40h of boss portions 40g. Then, a bolt 64 is screwed into bolt hole 40h of boss portion 40g through attachment hole 56a of top cover 55 and an interposal member 65, such as a rubber cushion, thereby fastening top cover 55 onto body 40 of air cleaner 20.
Also, on the top surfaces of cylinder head 7 and bonnet cover 8 are formed respective vertical bolt holes 62 and 63 for attachment of top cover 55. The remaining attachment holes 56a and 56a of top cover 55 are arranged to correspond to respective bolt holes 62 and 63. Then, bolts 64 and 64 are screwed into bolt holes 62 and 63 through attachment holes 56a of top cover 55, interposal members and bosses, respectively, thereby fastening top cover 55 onto cylinder head 7 and bonnet cover 8.
Furthermore, as shown in
Furthermore, attachment hole 53b formed on lower end portion 53 of side cover 51 is arranged to correspond to the bolt hole in boss portion 2c projecting from the front surface of cylinder block 2. Then, a bolt 66 is screwed into the bolt hole of boss portion 2c through attachment hole 53b of side cover 51 and an interposal member 67, thereby fastening side cover 51 onto cylinder block 2.
Furthermore, upper end portion 54 of side cover 51 is fitted onto front edge portion 58 of top cover 55 so that attachment holes 59a and 59a on front edge portion 58 correspond to respective attachment holes 54b and 54b on upper end portion 54 of side cover 51. Then, a bolt 69 is screwed into nut 68 on upper end portion 54 interposing through attachment holes 54b and 59a, thereby fastening side cover 51 onto top cover 55. In this way, top cover 55 and side cover 51 are joined so as to form approximately inverse L-like shaped cover 50, thereby achieving better appearance of engine 1. Alternatively, top cover 55 and side cover 51 may be integrally formed. In this case, attachment of cover 50 onto engine 1 is made easier.
At a joint between side cover 51 and top cover 55, a circular opening is formed by fitting arcuate portion 54c of recess 54a formed in upper end portion 54 of side cover 51 and arcuate portion 59b formed in front edge portion 59 of top cover 55. Control shaft 39a of decompressor 39 is protruded from the opening. Decompressor lever 39b fixed on the outside end of control shaft 39a is positioned below top surface 56 of top cover 55 and above projecting portion 52 of side cover 51 so as not to protrude to the outside of top cover 55 and side cover 51. Therefore, decompressor 39 is operable by decompressor lever 39b in the state that cover 50 is attached on engine 1, thereby keeping good appearance of engine 1.
In this way, top cover 50 is made up of separable top cover 55 and side cover 51, thereby facilitating attachment of cover 50 onto engine 1. Furthermore, maintenance of engine 1 is also facilitated because top cover 55 or side cover 51 can be removed separately from engine 1 so that parts desired to be detached from engine 1 can be easily detached.
Furthermore, sound insulation is improved because cylinder head 7 is covered by cover 50 which blocks out noise caused by cylinder head 7. More in detail, the noise caused by cylinder head 7 is reduced because three sides (out of front, rear, left and right sides) of cylinder head 7 are covered by fuel tank 10, air cleaner 20 and muffler 9, the remaining one side of cylinder head 7 is covered by side cover 51, and the upper side of cylinder head 7 is covered by top cover 55.
In addition, users are prevented from accidentally touching exhaust pipe 34 because side cover 51 covers exhaust pipe 34 which is disposed in the exposed side of cylinder head 7, that is, in the side where devices such as muffler 9 are not disposed.
Furthermore, cover 50 attached on the main body of engine 1 as described above functions as a guiding plate to guide the cooling air from fan 35 to exhaust pipe 34 disposed on the opposite side to fan 35.
More specifically, as shown in
In this way, cover 50 serves as a guide plate for guiding cooling air from fan 35 to exhaust pipe 34 via cylinder head 7. Therefore, cylinder head 7, bonnet cover 8, and exhaust pipe 34 disposed on the opposite side to cylinder head 7 can be cooled by the cooling air.
On the other hand, the rest of the divided cooling air is led into cylinder head 7 by partition walls 40b, 40c and 40d. The cooling air cools cylinder head 7 from the inside thereof. After getting out of cylinder head 7, the cooling air reunites with the other divided part of cooling air getting out of the space between top cover 55 and bonnet cover 8, and, finally, the reunited cooling air is let out from the right and left sides and openings 52a, 52b and 52c of projecting portion 52 of side cover 51.
Thus, due to openings 52a, 52b and 52c formed on the side surface of side cover 51, the cooling air flowing out from the cylinder head 7 side can be sufficiently drawn out from side cover 51 without staying inside, thereby improving cooling efficiency. In addition, the weight of side cover 51 is reduced by the total areas of openings 52a, 52b and 52c.
Here, cooling air from fan 35 also flows through a space between cylinder block 2 and muffler 9 and through a space between cylinder block 2 and fuel tank 10. The cooling air passes through the space between cylinder block 2 and muffler 9 and the space between cylinder block 2 and fuel tank 10 cooling these devices, and, finally, it is drawn out from the lateral sides of side cover 51.
Referring to
As shown in
While muffler 9 and fuel tank 10 are arranged to project over and forward of cylinder head 7, cover 70 is spaced from cylinder head 7 so that a top surface of cover 70 is substantially aligned with one, two or all of top surfaces of muffler 9, fuel tank 10 and air cleaner 20, and a side surface of cover 70 is substantially aligned with at least one of side surfaces (front surfaces) of muffler 9 and fuel tank 10. In this way, projections and depressions on the outer surface of engine 1 are reduced, thereby improving appearance of engine 1.
As shown in
Now, description will given of a supporting structure of cover 70.
Cover 70 is attached on engine 1, being supported by housing portions of respective fuel tank 10 and air cleaner 20 and by an outer surface of cylinder block 2. Alternatively, cover 70 may be supported by bonnet cover 8 or cylinder head 7.
Firstly, description will be given of a supporting structure for cover 70 by the housing portion of fuel tank 10.
As shown in
Furthermore, as shown in
Next, description will be given of a supporting structure for cover 70 by the housing portion of air cleaner 20.
As shown in
Bolts 75 are screwed into the respective bolt holes of attachment portion 20b through insertion hole 71a of top cover 71 and rubber cushion 76 as an interposal member, thereby supporting cover 70 onto air cleaner 20. Here, rubber cushion 76 is also formed thereon with insertion holes for inserting bolts 75.
Next, description will be given of a supporting structure for cover 70 by cylinder block 2.
As shown in
Bolts 75 are screwed into the respective bolt holes on attachment portion 2d through insertion hole 72b on side cover 72 and rubber cushion 76 as an interposal member, thereby firmly supporting side cover 72 onto cylinder block 2.
In this way, cover 70 is supported on the housing portion of fuel tank 10 and air cleaner 20 and the outer surface of cylinder block 2.
Due to the above structure, cover 70 can be vibratory-isolatingly supported on the main body of the engine, thereby improving sound insulation to reduce noise.
Furthermore, in a configuration where fan 35 is arranged behind cylinder block 2, as detailed later, cooling air from fan 35 can be guided by cover 70 so as to be led into a space between cylinder head 7 and cover 70, thereby improving the efficiency of cooling cylinder head 7, bonnet cover 8, etc.
In addition, even in a configuration where exhaust pipe 34 is arranged in the exposed side of cylinder head 7, that is, in the side where devices such as muffler 9 are not disposed, cover 70 covers exhaust pipe 34 so that users are prevented from accidentally touching exhaust pipe 34. Furthermore, cover 70 can be used as a means for covering a base portion of muffler 9 (a joint between muffler 9 and exhaust pipe 34).
Here, cover 70 on the housing portions of the above-mentioned devices does not always require rubber cushions 74 and 76. Alternatively, cover 70 may be fixed onto engine 1 by means of direct bolting, for example, without any vibration-absorbing interposal member.
Now, detailed description will be given of the supporting structure of cover 70 focusing on vibration-reducing mechanism.
In this embodiment, cover 70 is made up of a bending-pressed metal plate member. For this reason, cover 70 is vibratory-isolatingly supported on the main body of engine 1 so as to be prevented from resonating with engine 1 to cause metallic noise when engine 1 is driven.
Here, in this embodiment, cover 70 is made up of a metallic plate member and vibratory-isolatingly supported on the main body of engine 1 via a rubber cushion 74 which is an elastic member. However, this configuration is not limitative. Alternatively, a cover itself may be made up of an elastic member such as a resinous member, for example, to have vibration-absorbing effect. Any other configuration is possible as long as the cover is attachable on engine 1.
Now, description will be given of a configuration for controlling decompressor 39 in the state that cover 70 is attached on engine 1.
Side cover 72 of cover 70 is formed on a top surface thereof with an insertion hole 72a for inserting control shaft 39a of decompressor 39. Control shaft 39a projects to the outside from insertion hole 72a. On the outer end of control shaft 39a is fixed decompressor lever 39b. The diameter of insertion hole 72a substantially corresponds to the outer diameter of control shaft 39a. Therefore, an exposed area of cylinder head 7 in insertion hole 72a is negligibly small.
In this way, decompressor lever 39b is arranged outside side cover 72 to be operable for controlling decompressor 39 while keeping the silent condition that cover 70 is attached on engine 1.
Furthermore, the operating portion of decompressor 39 is disposed below the top surface of cover 70. In the present embodiment, decompressor lever 39b serves as the above-mentioned operating portion of decompressor 39, and does not jut out above cover 70, thereby keeping good appearance of the top surface of engine 1.
Now, description will be given of cooling structure of cylinder block 2.
As shown in
The cooling air cools the rear surface of cylinder head 7, and further cools the side surfaces of cylinder block 2, cylinder head 7, etc. while passing through cylinder block 2 and through a space between cylinder head 7 and devices such as muffler 9 and fuel tank 10.
Furthermore, as shown in
As a result, cover 70, which is arranged to cover the top side and the one side (front side) of cylinder block 2, functions as an air guiding plate to lead cooling air from fan 35 to the opposite side of cylinder block 2 to fan 35.
As shown in
In this way, the cooling air from fan 35 is guided by cover 70 to cool cylinder head 7, bonnet cover 8, etc. In addition, the cooling air also flows through a space between muffler 9, fuel tank 10 and cylinder block 2 to cool cylinder block 2.
Next, description will be given of an effect of the layout of cover 70 relative to the devices including air cleaner 20 provided on engine 1.
As described above, muffler 9 and fuel tank 10 are disposed on the left and right sides of cylinder head 7, respectively. Air cleaner 20 is disposed on the rear side of cylinder head 7 (one of the sides where neither muffler 9 nor fuel tank 10 are disposed).
Further, top cover 70, which is formed to have an approximate inverse L shape in a section view, comprises top cover 71 and side cover 72. Side cover 72 is disposed on the opposite side of cylinder head 7 to air cleaner 20 (that is, on the front side of cylinder head 7).
Therefore, the front, rear, left and right sides of cylinder head 7 are covered by side cover 72, air cleaner 20, fuel tank 10 and muffler 9, respectively, and the top of cylinder head 7 is covered by top cover 71. As a result, the top and the four sides of cylinder head 7, bonnet cover 8, etc. are all covered, thereby improving sound insulation to reduce noise generated from cylinder head 7, bonnet cover 8, etc.
In addition, by entirely covering cylinder head 7, users are prevented from accidentally touching exhaust pipe 34, and the appearance of engine 1 is improved.
As described above, the engine cover structure according to the present invention has the merit of improving sound insulation so that noise generated from the cylinder head is reduced, and also has the merit that the cylinder head and the exhaust pipe are cooled by cooling air from the fan.
Number | Date | Country | Kind |
---|---|---|---|
2003-068934 | Mar 2003 | JP | national |
2003-365904 | Oct 2003 | JP | national |
The present application is a Continuation of PCT Application No. PCT/JP2004/002091, filed on Feb. 23, 2004, which is incorporated in its entirety herein by reference thereto.
Number | Name | Date | Kind |
---|---|---|---|
3521726 | Freyn | Jul 1970 | A |
3949727 | Thien et al. | Apr 1976 | A |
4142503 | Hatz et al. | Mar 1979 | A |
5033578 | Absenger | Jul 1991 | A |
5161490 | Iwata et al. | Nov 1992 | A |
Number | Date | Country |
---|---|---|
3 222822 | Oct 1991 | JP |
4-69648 | Jun 1992 | JP |
5 34472 | May 1993 | JP |
5-47377 | Jun 1993 | JP |
8 232654 | Sep 1996 | JP |
Number | Date | Country | |
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20060048742 A1 | Mar 2006 | US |
Number | Date | Country | |
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Parent | PCT/JP2004/002091 | Feb 2004 | US |
Child | 11219912 | US |