DE1283042B - Lubricating oil pump - Google Patents

Description

Lubricating Oil Pump The invention relates to a lubricating oil pump with a piston that controls the pumping process and a reduction gear rotatable about its longitudinal axis and back and forth in the longitudinal direction by means of a lifting disc is displaceable forth, with between the cam plate and the output-side toothed element of the reduction gear, a pressurized one arranged concentrically to the piston standing compression coil spring is provided which engages the cam disk with an abutment holds, and further between the reduction gear and the Piston an overrunning clutch is arranged, which is a direct rotary drive of the Piston, e.g. B. by a handwheel, allowed with increased speed.

For example, lubricating oil pumps of the type mentioned above can be found Use for metered fresh oil lubrication of small two-stroke petrol engines. There for Lubrication only small quantities of oil are required, is usually the lubricating oil pump Driven by the crankshaft with a very high reduction ratio. Now, however, have to follow the first assembly as well as after an engine repair the empty oil lines completely be refilled. Since this with the operational, slow operation of the Lubricating oil pump would take too long, it is known to be between the reduction gear and because piston to provide an overrunning clutch that allows for rapid Filling of the oil lines supplied by the pump, the piston bypassing the reduction gear to be driven directly by hand at increased speed.

In the known lubricating oil pumps of the type mentioned, this is an overrunning clutch designed as a sprag or pawl freewheel. Such a freewheel makes it more expensive however, the design of the lubricating oil pump increases its space and requires some maintenance from time to time in view of the inevitable wear and tear.

The invention is therefore based on the object, avoiding them These shortcomings to create a lubricating oil pump of the type mentioned, which compared to the known designs due to a simpler structure, a lower one Space requirement and a greater freedom from maintenance.

According to the invention, this object is achieved in that the helical spring designed as an overrunning clutch and with the piston or the gear element on the output side of the reduction gear is firmly connected in both directions of rotation, while with the other element only in one direction of rotation a non-positive, in the other direction of rotation, on the other hand, there is an automatically releasing connection.

In the embodiment according to the invention, the helical spring thus fulfills a multiple function: it keeps the piston stroke disc in engagement with one Against the bearing and at the same time cushions the piston during its stroke movement. Continues to broadcast In normal operation they apply the torque from the reduction gear to the piston, whereby however, it allows an axial longitudinal displacement of the same in addition to the rotary movement. Finally, said helical spring also forms the overrunning clutch by the connection between the toothed element of the reduction gear on the output side and the piston is automatically released by the spring when this immediately (for example by an external handwheel) with a higher speed than by the one on the output side Toothed element of the reduction gear is driven.

By eliminating a separate upper hoop freewheel, the constructive Structure of the lubricating oil pump is significantly simplified. At the same time, their space requirements are reduced and achieved greater freedom from maintenance.

In a further embodiment of the invention, this can be done in one direction of rotation detachable spring end arranged in a recess of the toothed element on the driven side be and the recess have an inclined surface that the spring end at immediate Rotary drive, d. H. by hand drive, pushes out of the recess. Through this training a further space saving is achieved; In addition, the technical effort continues decreased.

Some exemplary embodiments of the invention are shown in the drawings. It shows F i g. 1 shows a longitudinal section through a lubricating oil pump, FIG. 2 shows a section through the upper part of the hat-shaped worm wheel along the line A-B in FIG. 1 rotated by 90 °, FIG. 3 shows another embodiment of the hat-shaped worm wheel in plan view.

F i g. 4 shows a section through the worm wheel along the line C-D in Fig. 3, fig. 5 shows another embodiment of the upper worm wheel part in plan view, F i g. 6 shows a section through the worm wheel along the line E-F in FIG. 5, Fig. 7 a worm wheel pressed from sheet metal in plan view, F i g. 8 shows a section through the worm wheel along the line G-H in FIG. 7th

The lubricating oil pump shown in FIG. 1 is contained in a pump housing 1 a piston 2, which is used to dispense oil from a supply channel 3 to promote in a drainage channel 4. For this purpose, the piston 2, which is in the area of the two channels 3 and 4 is provided with a conveyor channel 5, into a back and forth reciprocal lifting movement as well as a simultaneous rotary movement about its longitudinal axis offset.

A worm 6 is mounted in the pump housing 1, which is driven by the crankshaft of the engine to be lubricated with fresh oil is driven and with an output side Toothed element, preferably a cup-shaped worm wheel 7, is in engagement. The worm wheel 7 sits freely rotatably on the upper shaft 2 a of the piston 2. This is firmly connected to a lifting disc 2 b, the profiled underside on one Bolt 8 rests.

In the hollow worm wheel 7, a helical spring 9 is arranged, which in the embodiment according to FIGS. 1 and 2 engages at its lower, bent end 9 a in a blind hole 10 of the lifting disk 2 b and is thereby firmly connected to the lifting disk with regard to torque transmission.

The upper, likewise bent end 9 b of the helical spring 9 engages - as in particular FIG. 2 shows a slot-like recess 11 in the bottom of the cup-shaped worm wheel 7. This recess 11 is bounded by two inclined surfaces, one of which produces a non-rotatable connection between the worm wheel 7 and the helical spring 9 in one direction of rotation, while the second inclined surface 11 a in the other direction of rotation establishes the connection between the worm wheel 7 and the helical spring 9 cancels. Instead of the cup-shaped worm wheel, a sleeve-shaped worm wheel could also be used which is connected to a disk (e.g. by screwing, soldering, welding or the like) which contains the recess 11.

With the shaft 22 a of the piston 2, which is in the cover 12 of the pump housing 1 is rotatably mounted, a hand wheel 13 is connected.

The mode of operation of the lubricating oil pump is as follows: FIG. 1 shows the piston 2 in its bottom dead center position. The oil supply is through locked the piston.

In normal operation, the piston 2 is slowly rotated about its longitudinal axis by the crankshaft of the engine via the worm 6, the worm wheel 7 and the helical spring 9. The worm wheel 7 moves here in the direction indicated by the arrow 14 in FIG. 2, so that the left inclined surface of the slot-like recess 11 rests in the bent end 9 b of the helical spring 9 and thereby a non-rotatable connection between the worm wheel 7 and the helical spring 9 is ensured. At the same time, the helical spring 9, which rests with its two outermost turns on the worm wheel 7 on the one hand and on the lifting disc 2 b on the other, presses the latter with its profiled underside on the bolt B. This underside of the lifting disc 2 b causes the piston 2 to rotate at the same time moves up and down in the longitudinal direction. When the piston is moved in the upper arrow direction, the delivery channel 5 of the piston 2 is rotated from the channel 4 of the housing 1 to the channel 3. The piston then assumes the position shown in dotted lines. The oil flowing into the channel 3 flows into the space 5 a and, as the piston continues to rotate and at the same time lowering it, enters the drain channel 4, from where it is the machine to be lubricated, e.g. B. an internal combustion engine, is metered.

If necessary (especially after the initial assembly as well as after a possible engine repair) the lines connected to the drainage duct 4 more quickly To be able to fill with lubricating oil, the handwheel 13 is operated so that the with the lifting disc 2 b over the bent end of the spring 9 a firmly connected helical spring 9 rotates in the direction of arrow 15 (see FIG. 2). The bent end of the spring 9 b consequently slides on the right inclined surface of the slot-like recess 11 down, so that the connection between the worm wheel 7 and the coil spring 9 is solved. It can therefore be slow at a standstill (or slow from the crankshaft) driven) worm wheel 7 of the piston 2 with the handwheel 13 faster than over the worm gear rotated and in this way the desired rapid filling of the oil channels can be achieved. The coupling connection between the worm wheel 7 and the coil spring 9 is then automatically restored as soon as the worm wheel 7 rotates faster than the coil spring 9.

While in the F i g. 1 and 2, the recess 11 provided with two inclined surfaces in the bottom 7a of the worm wheel 7 is designed as a radial slot, FIGS. 4 to 8 some variants for the type of anchoring of the detachable spring end on the worm wheel 7: In the embodiment according to FIGS. 3 and 4, an inclined bore 17 is provided in the bottom 16 of the worm wheel connected to the spring end 9b. In the arrangement according to FIGS. 5 and 6, the bottom 18 of the cup-shaped worm gear 7 has a recess 19, one boundary surface of which is perpendicular to the disk plane, while the other boundary surface is inclined. This design is particularly useful when the worm wheel is made of investment casting or sintered material.

The F i g. 7 and 8 finally show a variant in which the worm wheel is made of sheet metal, the base 20 having a tongue 21 produced by stamping. The tongue 21 represents an inclined surface which releases the coupling connection between the reduction gear and the piston when the latter is driven by hand at increased speed. The bottom 20 can be made thicker than the rest of the worm wheel for the purpose of easier deformation.

While always assumed in the embodiments described so far was that the coil spring 9 with the lifting disc 2 b for torque transmission firmly connected, but the connection with the worm wheel 7 as an overrunning clutch is formed, the opposite solution can of course also be selected, d. H. that the fixed connection for the torque transmission in the worm wheel and the releasable connection is arranged in the lifting disc 2 b.

If relatively large torques have to be transmitted, what is the case at start-up, when it is very cold and correspondingly viscous oil the risk that the spring 9 or individual turns of the same out of their intended Shift the position or unscrew it and thereby disrupt the function.

The dimensions of the helical spring 9 and the one for receiving the spring Serving cavity in the worm wheel 7 are therefore expediently chosen so that the coil spring is enclosed in this cavity with little clearance and so against an impermissible expansion of individual spring coils is protected.

To achieve the desired ratio of compressive strength to flexural strength of the helical spring 9 and thus to ensure that the pump works reliably, it is advisable to the spring wire has an elongated, preferably rectangular or elliptical cross section to give, wherein the cross-sectional longitudinal axis runs approximately perpendicular to the spring longitudinal axis. In this way, without impairing the desired compressive elasticity, the Bending rigidity required for the transmission of the torque is achieved.

Claims (4)

Claims: 1. Lubricating oil pump with a piston that controls the pumping process and is rotatable about its longitudinal axis via a reduction gear and displaceable in the longitudinal direction by means of a lifting disk, with a compression coil spring arranged concentrically to the piston being provided between the lifting disk and the gear element of the reduction gear on the output side holds the cam plate in engagement with an abutment, and furthermore an overrunning clutch is arranged between the reduction gear and the piston, which allows a direct rotary drive of the piston at increased speed, characterized in that the helical spring (9) is designed as an overrunning clutch with the piston (2) or the output-side toothing element (7) of the reduction gear is firmly connected in both directions of rotation, while with the other element (7 or 2) only a non-positive connection in one direction of rotation and a non-positive connection in the other direction of rotation e there is a self-releasing connection. 2. Lubricating oil pump according to claim 1, characterized in that the detachable in one direction of rotation spring end (9 b) is arranged in a recess (11, 17, 19, 21) of the output-side toothed element (7) and the recess has an inclined surface which the Pushes the end of the spring out of the recess when the rotary drive is direct. 3. Lubricating oil pump after Claim 1 and / or 2, in which the reduction gear by a worm and a worm wheel is formed, characterized in that the helical spring (9) is arranged in the worm wheel (7) and is guided in this over its entire length. 4. Lubricating oil pump according to one or more of claims 1 to 3, characterized in that that the helical spring (9) is preferably rectangular in a manner known per se or elliptical spring wire cross-section with approximately perpendicular to the longitudinal axis of the spring Has cross-sectional longitudinal axis. Publications considered: German patent specification No. 719 092; British Patent No. 335,030.