The present invention relates to an improvement in a power-storage-type engine starting system that utilizes power stored in a spring to start a multi-purpose engine.
Japanese Patent Application Laid-Open Publication No. 2004-263615 discloses a power-storage-type recoil starter. In the disclosed recoil starter, a reel support shaft attached to the fixed side of an engine via a main body casing is provided on the extension axis of a crankshaft, and a recoil pulley on which a recoil rope is wrapped is rotatably attached to the reel support shaft.
In the power-storage-type recoil starter described above, the main body casing is attached to the engine. The reel support shaft is attached to the center part of the main body casing so as to be positioned on the extension axis of the crankshaft. A rope reel is rotatably attached to the reel support shaft. The recoil rope is wrapped onto the rope reel. A handle is attached to the end of the recoil rope.
The rope reel is connected to a spring case via a speed reduction mechanism, and a cam wheel is connected to the spring case via a power storage mechanism. A rotating member is connected to the cam wheel via a transmission mechanism. The rotating member is attached to the crankshaft.
The transmission mechanism is provided between the cam wheel and the rotating member so that the rotation of the engine when the engine starts is not transmitted to the recoil starter. The transmission mechanism is composed of a plurality of cam claws formed on the external peripheral surface of the cam wheel, and a centrifugal ratchet provided to the rotating member so as to be engaged with the cam claws by centrifugal force.
However, in the conventional recoil starter, the centrifugal ratchet that constitutes the transmission mechanism is structured so as to separate from the cam claws by centrifugal force, and since the centrifugal ratchet is necessarily provided at the crankshaft and to the outside in the radial direction of the cam claws, a cylindrical rotating member must be attached to the crankshaft, and the cam wheel must be rotatably supported by the reel support shaft. Specifically, a pulley support shaft must be provided on the extension axis of the crankshaft, and the profile of an engine that includes the recoil starter is enlarged in the direction of the crankshaft.
An object of the present invention is to reduce the size of an engine that is provided with a power-storage-type recoil starter.
According to the present invention, there is provided a power-storage-type engine starting system which comprises: a power-storage-type recoil starter; a crankshaft rotatable by the recoil starter to start the engine; a recoil pulley rotatably supported by a pulley support shaft and having a recoil rope wrapped therearound; a wheel member adapted to be rotatably supported by the crankshaft of the engine; and a power storage mechanism for storing power by pulling the recoil rope and rotating the recoil pulley, the power storage mechanism being provided between the recoil pulley and the wheel member, wherein the crankshaft has an end passing through the pulley support shaft and inserted into a one-way clutch which is attached to inside of the wheel member.
When the engine starts, rotation of the crankshaft is not transmitted to the wheel member by the one-way clutch. Consequently, there is no need for a structure in which a centrifugal ratchet and cam claws engage with each other, as in the conventional technique; there is no need for a structure such as that of the conventional technique in which a cylindrical rotating member is attached to the end of the crankshaft, and a reel support shaft such as in the conventional technique is provided on the extension axis of the crankshaft; and the dimensions of the power-storage-type recoil starter in the axial direction of the crankshaft can be reduced. Consequently, the size of the engine started by the power-storage-type recoil starter can be reduced.
Preferably, the power storage mechanism comprises a coil spring in which a number of turns between the recoil pulley and the wheel member gradually increases and power is stored by pulling of the recoil rope.
Desirably, the wheel member comprises a boss body through which the shaft end of the crankshaft passes, and the boss body has a front spring chamber for accommodating the power storage mechanism, the power storage mechanism being formed between the recoil pulley and a rear boss provided to a rear part of the boss body.
In a preferred form, the one-way clutch meshes with the crankshaft when power is transmitted from the power storage mechanism to the crankshaft, and the wheel member and the crankshaft thereby rotate integrally with each other via the one-way clutch.
A preferred embodiment of the present invention will be described in detail below, by way of example only, with reference to the accompanying drawings, in which:
An engine 10 shown in
The reference numeral 23 refers to a head cover for covering an end opening of the cylinder head 13, and the reference numeral 24 refers to a starter handle (grip) that is provided to the power-storage-type recoil starter 40.
As shown in
The reference numeral 33 refers to an exhaust port of the muffler 16. The air cleaner 17 has an air cleaner cover 34.
As shown in
The reference numeral 54 refers to a bearing for rotatably supporting the crankshaft 31, and the reference numeral 55 refers to a seal member.
The one-way clutch 51 is provided between the assist boss 47 and the shaft end 31a of the crankshaft 31; i.e., the shaft end 31a of the crankshaft 31 is configured to pass through the one-way clutch 51.
The fixed plate 42 is composed of a plate-shaped part 42b, a plurality of attachment bosses 42d formed on a back surface 42c of the plate-shaped part 42b so as to protrude to the rear, an annular concave part 42e formed in the center of the plate-shaped part 42b, and a cylindrical shaft part 42a formed on an internal wall of the annular concave part 42e.
The starter cover 21 is attached to the external periphery of the fixed plate 42.
The attachment bosses 42d are attached by the screws 41 to crankcase bosses 11b formed on the front surface 11a of the crankcase 11.
A pulley boss 43a formed integrally with the rear part of the recoil pulley 43 is inserted into the annular concave part 42e. The cylindrical shaft part 42a rotatably supports the pulley boss 43a of the recoil pulley 43. A gap is formed between an external peripheral surface 42f of the cylindrical shaft part 42a and the shaft end 31a of the crankshaft 31.
The recoil pulley 43 is composed of a pulley main body 43b, the pulley boss 43a formed at the rear of the pulley main body 43b, and a front cylinder part 43c formed at the front of the pulley main body 43b.
A rear spring chamber 56 for accommodating the returning spring 46 is formed between the cylindrical shaft part 42a of the fixed plate 42 and a rear cylinder part 43d formed at an end of the pulley boss 43a. One end each of the returning spring 46 is attached to the rear cylinder part 43d and the cylindrical shaft part 42a. A rope groove 43e is formed along the entire external periphery of the pulley main body 43b. The recoil rope 44 is wrapped into the rope groove 43e.
When the recoil rope 44 is pulled and the recoil pulley 43 is rotated about the cylindrical shaft part 42a of the fixed plate 42, the number of turns of the returning spring 46 gradually increases, and power is stored therein. When pulling of the recoil rope 44 is stopped and the recoil rope 44 is relaxed, the recoil pulley 43 is rotated in reverse by the stored power, and the recoil pulley 43 returns to the original position.
The assist boss 47 is composed of a boss body 47a through which the shaft end 31a of the crankshaft 31 passes, and a flange part 47b that extends in the radial direction from an external peripheral surface of the boss body 47a.
A rear boss 47c is provided at the rear of the boss body 47a, a front spring chamber 58 for accommodating the assist spring 48 is formed between the rear boss 47c and the front cylinder part 43c of the recoil pulley 43, and one end each of the assist spring 48 is attached to the rear boss 47c and the front cylinder part 43c.
A large-diameter hole 47d into which the one-way clutch 51 is pressed is formed on the internal peripheral surface of the boss body 47a. A gap is formed between an internal peripheral surface 47e of the rear boss 47c and the shaft end 31a of the crankshaft 31.
The assist spring 48 is a coil spring in which the number of turns between the recoil pulley 43 and the assist boss 47 gradually increases and power is stored when the recoil rope 44 is pulled and the recoil pulley 43 is rotated about the cylindrical shaft part 42a of the fixed plate 42. When pulling of the recoil rope 44 is stopped, and the state of pulling is maintained after power is stored in the assist spring 48, the stored power is transmitted to the crankshaft 31 via the assist boss 47 and the one-way clutch 51, the crankshaft 31 is rotated, and the engine starts.
When power is transmitted to the crankshaft 31 from the assist spring 48, the one-way clutch 51 is in a meshed state, and the assist boss 47 and the crankshaft 31 rotate in integral fashion via the one-way clutch 51.
A shown in
Depressions 61a are formed in the internal peripheral surface of the outer wheel 61 so as to correspond to the rollers 63, and cam surfaces 61b formed so as to gradually approach the shaft end 31a of the crankshaft 31 are formed in the depressions 61a.
The retainer 62 is provided with elastic members 64 for retaining the rollers 63 in the circumferential direction of the one-way clutch 51.
In the drawings, the rollers 63 are kept in a free state in the depressions 61a of the outer wheel 61. The outer wheel 61 rotates in the direction of the arrow with respect to the shaft end 31a of the crankshaft 31.
In
An operation of the power-storage-type recoil starter 40 described above will next be described.
The starter handle 24 is attached to one end of the recoil rope 44, and the other end of the recoil rope 44 is attached to an external peripheral part of the recoil pulley 43.
One end of the assist spring 48 is attached to an internal peripheral part of the recoil pulley 43, and the other end of the assist spring 48 is attached to an external peripheral part of the assist boss 47. The outer wheel 61 of the one-way clutch 51 is pressed in on the internal peripheral surface of the assist boss 47, and the plurality of rollers 63 of the one-way clutch 51 is arranged so as to be able to touch the external peripheral surface of the shaft end 31a of the crankshaft 31.
In the structure described above, the rotational force transmitted to the recoil pulley 43 via the recoil rope 44 by the pulling of the starter handle 24 acts on the assist spring 48 so as to increase the number of turns thereof and store power, and the rotational force is furthermore transmitted to the assist boss 47. The assist boss 47 is thereby rotated, causing the one-way clutch 51 to rotate so as to mesh with the crankshaft 31 and to cause the crankshaft 31 to rotate.
A piston connected to the crankshaft 31 of the engine via a connecting rod is positioned at the bottom dead center (BDC) of the engine expansion (EXP) stroke, for example, as indicated by a black circle in the piston position display chart shown in the drawing, and the crankshaft is stopped in a rotation position that corresponds to this piston position. The white arrow in the drawing indicates the rotation position of the crankshaft 31 (the white arrow points downward, indicating that the piston is positioned at the bottom dead center). In the piston position display chart, reference character EXP indicates an expansion stroke; EXH an exhaust stroke; INT an intake stroke; and COM a compression stroke,
The black circle 71 on the recoil pulley 43, and the black triangle 72 on the assist boss 47 in the drawing indicate the target rotation positions of the recoil pulley 43 and the assist boss 47, respectively.
Beginning in the state shown in
Beginning in the state shown in
Rotation range of the crankshaft 31 at this time is the run-up zone of the rotation of the crankshaft 31. The recoil pulley 43, the assist spring 48, the assist boss 47, the one-way clutch 51, and the crankshaft 31 rotate substantially integrally, and there is almost no twisting of the assist spring 48.
In this rotation position of the crankshaft 31, since the compression pressure inside the combustion chamber increases, a response is suddenly felt when the recoil rope 44 is pulled by the starter handle 24, and a large pulling force is required.
Beginning in the state shown in
When the rotational force stored by the assist spring 48 in the state shown in
When the crankshaft 31 in the state shown in
As shown in
The generator 78 is composed of a stator 82 attached to the cover member 75 by a plurality of bolts 81; and a rotor (not shown) attached to the flywheel 77 so as to rotate near the periphery of the stator 82.
The stator 82 is composed of a stator core 84 and a stator coil 85 that is wrapped onto the stator core 84.
As shown in
The one-way clutch 51 was positioned further forward than the assist spring 48 in the present embodiment, as shown in
Obviously, various minor changes and modifications of the present invention are possible in light of the above teaching. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.
Number | Date | Country | Kind |
---|---|---|---|
2008-147088 | Jun 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3754543 | Harkness | Aug 1973 | A |
5161489 | Morooka | Nov 1992 | A |
7201130 | Hashiba | Apr 2007 | B2 |
7343891 | Chang | Mar 2008 | B1 |
7658176 | Fattorusso et al. | Feb 2010 | B2 |
20030015162 | Harada et al. | Jan 2003 | A1 |
20050211216 | Otsuki | Sep 2005 | A1 |
Number | Date | Country |
---|---|---|
1384881 | Jan 2004 | EP |
2004-263615 | Sep 2004 | JP |
Number | Date | Country | |
---|---|---|---|
20090301425 A1 | Dec 2009 | US |