FR2883600A1 - Decompressor for heat engine, has eccentric that is returned to armed position by pin spring such that stopping of slid flat on axle integrated with eccentric is placed vertically - Google Patents

Abstract

The decompressor has an eccentric (A) that is positioned from a side of a distribution pinion which is provided opposite to two cams. The eccentric is movable between armed and disarmed positions. The eccentric is returned to the armed position by a pin spring (13) such that stopping of a slid flat of the eccentric on an axle integrated with the eccentric is placed vertically. A pushrod is pushed towards the top such that the pushrod half-opens an exhaust valve during the compression phase of an engine e.g. heat engine. An independent claim is also included for a mode of execution of a decompressor.

Description

DECOMPRESSOR WITH MASSELOTTE CENTRIFUGE

  The present invention relates to the field of mechanics and more particularly to the field of the gardening industry.

  It relates more particularly to a device that facilitates the use of small heat engines and especially those with high compression ratio.

  It relates specifically to a decompressor centrifugal feeder which reduces the force exerted by the user on the handle of the launcher at the start of the engine, characterized in that it comprises a weight (A) as shown in FIG. FIG. 1, which is brought back to the so-called armed position by a pinlike spring (13) as represented in FIG. 1, so that the edge of the flat (V) as represented in FIG. 1 on the integral axis (5) ) as shown in Figure 2 of the weight (A) as shown in Figure 1 is placed vertically and the pusher (7) as shown in Figure 2 is pushed upwards so that it opens the valve d exhaust (11) as shown in Figure 2 during the compression phase of the engine.

  This device makes it possible to reduce the force exerted on the launcher of the engine and thus facilitates the starting or the restart of this one for the user.

  In a preferred embodiment, the pusher ajars the exhaust valve (11) as shown in Figure 2 by a small distance between 0.3 and 2.00 mm. When the decompressor is disarmed, the exhaust valve is closed during the compression phase.

  Therefore, during the first explosion of the engine in the combustion chamber, the engine undergoes a sudden acceleration and under the effect of the centrifugal force exerted on the flyweight (A) as shown in Figure 1, it is moves in the direction of (A ') as shown in Figure 1 and therefore, the flat (V) as shown in Figure 1 passes to the horizontal position (H), which consequently eliminates the opening of the exhaust valve (11) as shown in Figure 2 during the so-called compression phase.

  The device according to the invention therefore has the advantage that it controls very precisely the height of the lifting of the compressor defined by construction. In addition, this lift is perfectly reproducible in series and this system can be easily manufactured industrially.

  Another advantage lies in the fact that the device according to the invention is very simple and that the cost of production is therefore very low.

  According to another embodiment of the device according to the invention, the cams and the teeth of the pinion are made of very resistant material, in particular heat and in general of moldable or machinable material, such as steel, cast iron or a heat resistant plastic material. The plastic material has the additional advantage of significantly reducing the operating noise generated by the gear teeth and the impact of the pushers on the cams. For similar reasons, once manufactured, the plastic mold of the cam shaft, the manufacturing costs of such a device decreases significantly. The plastic material used is preferably a high impact polystyrene or a high density polyethylene resistant up to 250 C. According to another advantageous embodiment of the invention, the eccentric (A) as shown in FIG. 3 can be positioned either on the of the timing gear opposite to the cams 3 and 4, that is to say the side of the cams 3 and 4 as represented in FIG. 3. Therefore, all we have to do is change the attachment of the eccentric (A) as shown in FIG. Figure 3 on the axis (5) as shown in Figure 3.

  In this second case the transverse immobilization of the axis (5) as shown in Figure 3 and the eccentric (A) as shown in Figure 3 relative to the timing gear is effected by means of circlips and washers put in place in (15 16 17 18 19 and 20).

  The axis (5) as shown in Figure 3 and the eccentric (A) as shown in Figure 3 are in this case, made integral in rotation by a flat on the axis (5) as shown in Figure 3 and in the eccentric (A) as shown in the corresponding figure.3.

  In the present invention, the centrifugal feeder decompressor system, while retaining the same principle, can therefore be the subject of two different embodiments which are described below in FIGS. 1 and 2 on the one hand and 3 on the other hand, whose differences are thus highlighted.

  The first embodiment is illustrated by FIGS. 1 and 2.

  The eccentric (A) is positioned on the side of the sprocket which is opposite to the two cams 3 and 4.

  Its immobilization in translation is ensured on one side by the natural abutment that is the distribution pinion 1, and on the other side, by a flat washer 21, itself bearing on the foundry of the crankcase (not shown here ).

  The axis 5 and the eccentric A are integral (these two parts can be either molded, evening welded or crimped).

  Figure 3 particularly illustrates the second embodiment.

  In this case of embodiment, the eccentric (A) and the axis (5) are immobilized in rotation relative to one another by a male flat on the axis (5) and an identical counterbore female on the eccentric (A). The eccentric (A) is located on the (A side) of the pinion (1) (opposite to the embodiment n 1, as shown in FIG. 3. The immobilization in translation of the eccentric ( A) with its axis (5), on the opposite side to the cams 3 and 4, by a circlip 16 and a flat washer 15 and the side of the cams 3 and 4, by a flat washer 17 resting on the side of the distribution gear on the shoulder H of the axis 5, an elastic washer 19, a flat washer 18 and a circlip 20. as shown in FIG.

  The assembly time of the axis assembly (5) + eccentric (A) + circlips + washers will be significantly longer because of the stacking of the various components, whereas in the execution mode n 1, the axis and the eccentric are monoblock, as shown in Figure 3.

  These two decompressor systems have particular advantages in two cases: Decompressor case in the so-called <disarmed> position. The flat on the axis (5) as shown in Figure 2 is horizontal (H) as shown in Figure 1 and therefore does not act on the pusher 7 when the eccentric (A) is in position AT'.

  The eccentric (A) is pulled to the A 'position by the centrifugal force (compressing the pin spring (13) towards (13') as shown in Figure 1 at the start of the motor.

  Decompressor case in the so-called <armed> position.

  The flat on the axis (5) as shown in Figure 2 is vertical (V) as shown in Figure 1 and pushes on the pusher (7) as shown in Figure 2 to open the valve (1) as shown in Figure 2 via the rocker arm shaft (8) as shown in Figure 2 and the rocker arm (9) as shown in Figure 2 articulated on the pivot (10) as shown in Figure 2. The eccentric (A ) as shown in Figure 2 is in the position A '. The eccentric is returned to the position (A) by the pin spring (13) as shown in Figure 1 when the engine is stopped (see Figure 2) (no centrifugal force).

  The following drawings show the peculiarities of the decompressor according to the invention.

  FIG. 2 shows in section the device comprising an axis (B) (B ') provided with a centrifugal feeder (A) arranged on the opposite side to the cams 3 & 4. The shaft also carries an exhaust cam (3) in contact with the rocker arm shaft (8) via an exhaust pusher (7) which controls the movement of the rocker arm (9) articulated on the fixed pivot (14), in turn actuating the valve of exhaust (11).

  Figure 1 shows the decompressor in the armed position, the flat part being in vertical position (V). If the compressor is disarmed, the flat is in the horizontal position (H).

  Figure 1 shows the operation of the weight (A). The return of the centrifugal flyweight (A ') to (A) is provided by the spring (13) hairpin. This ensures the rearming of (A ') in (A), with the engine stopped.

  In this device, the pin spring (13) is compressed under the effect of the centrifugal force at (13 ').

  Figure 3 shows a partial view of the mounting of the eccentric. The axis, in the working position being in vertical position, the eccentric (A) is held in position by means of a spring washer (19) which holds it in abutment against the shaft (5) with the washer plate (15) and circlip (20).

  The invention finds particular use in the design and production of small heat engines, especially for the production of lawnmowers, curbs, blowers / crushers for sheets, for generators or motor hoes etc. The decompressors according to the invention allow easy starting and also in case of stalling, easy restart.

Claims (12)

  1. Decompressor for thermal engines characterized in that it comprises a flyweight (A) movable between an armed position and a disarmed position which is brought back to the armed position by a pin spring (13) so that the edge the flat part (V) on the integral axis of the weight (A) comes to be placed vertically and in that the pusher (7) is pushed upwards so that it opens the exhaust valve (11) during the compressor phase of the engine.   2. A decompressor according to claim 1, characterized in that the pusher half-open the exhaust valve (11) with a distance between 0.3 and 2.0 mm depending on the setting adopted.   3. A decompressor according to claim 1, characterized in that the cams and the teeth of the distribution pinion are heat-resistant material, moldable or machinable.   4. Decompressor according to claim 1, characterized in that the cams and the teeth of the timing gear are made of steel or cast iron.   5. Decompressor according to claim 1, characterized in that the cams and the teeth of the distribution gear are made of plastic.   6. A decompressor according to claim 5, characterized in that the plastic material used for the distribution pinion is a polystyrene or a high density polyethylene.   7. The embodiment of the decompressor centrifugal feeder according to claim 1, wherein the eccentric (A) is positioned on the side of the timing gear (1) 35 which is opposite to the two cams (3) and (4) and whose immobilization is ensured on one side by the natural stop constituted by the sprocket (1) and on the other side by a flat washer (21) resting on the foundry of the crankcase, the axle (5 ) and the eccentric (A) being integral.   8. The embodiment of the centrifugal feeder compressor according to claim 7 wherein when the decompressor is in the disarmed position meplat on the axis (5) is in the horizontal position (H) and does not act on the pusher (7). ) when the eccentric (A) is in position (A) while the eccentric (A) is pulled to the position A 'by the centrifugal force due to the compression of the pin spring (13) at the start of the motor.   9. The embodiment of the centrifugal feeder compressor according to claim 7, wherein when the decompressor is in the so-called armed position, the flat on the axis (5) is placed in the vertical position (V) and exerts a pressure on the pusher ( 7) to open the valve (11) via the rocker rod (8) and the rocker arm (9) articulated on the pivot 10, and wherein the eccentric is in position A, the eccentric being brought back from the position A 'to the position (A) by the pin spring (13) when the engine is stopped.   10. The embodiment of the centrifugal feeder compressor according to claim 1, wherein the eccentric (A) and the axis (5) are immobilized in rotation relative to each other by a male flat (M). on the axis (5) and by an identical female countersink (M) on the eccentric (A).   11. Use of the decompressor centrifugal feeder according to one of claims 1 to 6, for thermal engines.   12. Use of the centrifugal feeder decompressor according to one of claims 1 to 6, for lawn mower engines.