SE450592B - HYDRAULIC PUMP - Google Patents

Description

If the dead chamber has a volume of 25 cm 3 and the cylinder a volume of 10 cm 3, a rotation of the oblique plate of about 360 (of a pressurizing stroke of 1800) is required to ensure that its pressure is raised to 400 bar.After the end of the discharge stroke, a rotation of about 300 is required.

Since the compressibility coefficient can vary from 1/22000 at -so ° c 1111 1 / 9soo at 1so ° c and since there may be microscopic air bubbles in the discharged liquid, it may happen that in practice the shaft of the pump must be rotated 500 to depressurize the piston - the chamber.

Attempts have previously been made to obviate these inconveniences by providing means for communicating the suction side with the dead chamber including a delay which ensures a relative pressure relief of the dead chamber prior to the establishment of said connection. This is especially the case with pumps. with oblique plate, which does not include valves but a crescent-shaped figure (lunule) engraved in the plate, the connection being made through the piston. The beginning of the crescent-shaped figure can now be placed in such a way that the connection appears only after a certain pressure relief time. At high pressures and low capacities - conditions that you encounter e.g. in pumps with variable cylinder volume - however, this leads to a reduction of the crescent-shaped figure in excessive proportion, the rotation necessary for the pressure relief is limited to 1800.

Furthermore, too high capacities, which for reasons of compactness are obtained by a large stroke of the pistons, the section of the passage in each piston is generally insufficient, so that this solution becomes impractical.

The object of the present invention is to provide a volumetric pump with valves for the suction, thereby avoiding the impact stones and difficulties stated above.

This object is achieved in that the pump according to the invention has the features which appear from the appended claims.

According to the invention, each piston is associated with an intake valve, which is returned to the closed position by a spring and is driven back towards its opening position by an opposing spring depending on the position of the piston and the phase in which the piston is located.

This counteracting force achieves during at least a part of the suction phase a value which is greater than the return force of the spring which drives the valve towards its closed position.

Thus, as soon as the return movement of the piston has allowed the dead chamber to be sufficiently depressurized, the valve can be opened under the influence of the counteracting force.

It can be noted that this pressure relief due to the movement of the piston is obviously accompanied by a restoration of energy to the drive shaft of the pump.

According to the invention, the counteracting force is obtained by means of an counteracting spring, which is compressed by some suitable means, such as a cam, depending on the position of the piston and during the suction phase.

The relative properties of the return spring, the counter-spring and the cam are determined as a function of the residual pressure beyond which the opening of the valve is desired.

A hydraulic pump with a valve for the suction is thus obtained, the suction valve opening with variable delay relative to the beginning of the suction phase of the piston, which delay is automatically adapted to the operating conditions (pressure and capacity) of the pump in such a way that the suction is opened when the pressure is opened. in the dead chamber, measured in relation to the pressure on the intake side, falls below a predetermined value, which should preferably be lower than 1S bar and of the size 3 to 5 bar.

The present invention further allows reversal of the direction of rotation of the inclined plate pump, which in the case of inclined plate pumps with crescent recess of known type necessitates an intervention for reversing the position of said crescent recess or figure.

The invention, which is applicable to hydraulic pumps of different types and with different types of valves, is described in more detail in the following with reference to the accompanying drawing.

Pig. 1 shows in a schematic sectional view the application of the invention to a pump with a fixed oblique plate and with a rotating cylinder: 2 shows in a schematic sectional view the application of the invention to a pump with a rotating oblique plate and with fixed pistons. Fig. 3 shows diagrammatically and in perspective a cam profile adapted to the types of pumps shown in Figs. 1 and 2. Figs. 4 shows in a schematic sectional view the adaptation of the invention to a pump with radial pistons. In Pig. Fig. 5 shows a cam profile adapted to the pump according to Fig. 4.

Pig. 6, 7 and 8 show different valve variants.

In Fig. 6, the valve of the contact type is cone to cone.

In Fig. 7, the valve is of the ball type.

In Fig. 8, the contact type valve is flat surface to flat surface.

Pig. Fig. 9 shows the control of the intake valve 11 in Figs. 1 and 2.

Pig. 10 is a longitudinal sectional view of the pump variant shown in FIG. 'Pig. 11 is a larger scale view of a detail included in Fig. 10.

As can be seen from the above figures, the pump according to the invention, which is of a volumetric type, comprises pistons 1 which compress fluid in chamber 2, which are assigned to intake pipes 3 and discharge lines 4.

Pig. 1 shows in axial section a pump with a fixed oblique plate 5, the pistons 1 being mounted in a rotating cylinder 6. The pistons are pressed by springs 1a against the plate 5, wherein sliding contact elements 7 are arranged therebetween.

In the example shown in Fig. 1, a cylinder top 6a is fixed to the rotating cylinder 6. In this cylinder top 6a, suction lines or channels 3 are arranged, which are in free communication with a volume Sa, in which an opening 3b for feeding of liquid results in. Said openings 3 communicate with the chamber Z of the pistons 1 via suction valves 11, each of which is moved to the closed position by a return spring 12. At the base of the chambers 2 and slightly above the suction valves 11, discharge lines or channels 4 are arranged, which are closed. These valves are hereby connected by springs 22. These valves are connected to a central chamber 23, which is connected by a double central piston 24a and 24b, between which a contact element 24c is arranged, to the outlet opening of the pump. The assembly 24a, 24b, 24c acts as a torque.

Pig. 2 shows a partial, axial section through a pump with rotating oblique plate 8, the pistons 1 being mounted in a fixed body 9 and pressed by springs 1a against the plate 8 with intermediate arranging sliding contact elements 7.

In the example shown in Fig. 2, elements which have the same reference numeral as in Fig. 1 are identical or analogous to the elements in Fig. 1.

Pig. 4 shows in a partial, axial section a pump with radial pistons, which are actuated by a cam 10 mounted on the shaft Z1 of the pump and which are driven back by springs 1a.

In the example shown in Fig. 4 are elements which have the same reference numeral as in fig. 1 and 2, identical or analogous to the elements therein.

According to the invention, each valve 11 is exposed not only to the force exerted by its return spring 12 but also to a counteracting force exerted in the opposite direction.

This force is variable as the cycle of the pump is traversed, so that the force in question is greater than the force from the return spring 12 during at least a part of the suction phase. In the example shown, this force is applied by a spring 13, which is composed of a cam 14, the profile of which is designed as a function of the properties of the spring 13, so that the counteracting force corresponds to the conditions described above.

A ball 15 is preferably placed between the spring 13 and the cam 14.

The cam 14 and the spring 13 are preferably so defined that the counteracting force is greater than the return force during almost the entire intake stroke of the piston.

The cam 14 and the spring 13 are preferably calculated in such a way that the counteracting force during the suction phase exceeds the return force by an amount suitable for equalizing an overpressure in the dead chamber of less than 15 bar and preferably of size 3 to S. bar.

The function is as follows: During the compression phase, the valve II is pressed against its seat in the closed position by the pressure from the liquid flowing through the line 4, the valve Z1, the rotary coupling 24 and the opening 25. The spring 12 is calculated in such a way that it is quite strong to obtain a quick return of the valve to the closed position at the beginning of the compression phase and to avoid any unsuitable bounce when the pump is operating at high speed. 10 15 20 ZS 30 35 40 450 5921 6 During the discharge phase, the cam 14 drives back the ball 15 and consequently compresses the spring 13, which thus exerts a counteracting force on the valve 11, which counteracting force exceeds the force from the spring 12. As the piston 1 returns to the chamber 2, the residual pressure remaining in said chamber 2 decreases at the end of the compression phase.As soon as the residual pressure falls below a value corresponding to the difference between the opposite forces exerted by the spring 11 and the spring 13, the latter tensioned by the cam 14, the valve ll opens.

It follows, firstly, that a sudden pressure drop, such as a pressure drop from 400 bar to 0, has been avoided, and the violent, strong pressure relief has been replaced by a weak one, e.g. of the size from 3 to 5 bar to 0, which is practically negligible both from an energy point of view and from a sound level point of view.

Secondly, it can be observed that with the device according to the invention the opening of the suction valve takes place when the overpressure in the dead chamber has fallen below a predetermined value, which takes place at a variable time in accordance with the operating or operating conditions of the pump. Thus, at high capacities and low pressures this opportunity will occur with little delay after the start of the suction phase, while at high pressures and low capacities the delay may be close to 1800.

Expressed in another way, the delay in opening the suction will thus automatically adapt to the operating conditions of the pump.

Pig. 6, 7 and 8 show that the intake valve can be designed in different ways, without this influencing the nature of the present invention. In Fig. 6, the valve of the contact type is cone to cone. In Fig. 7, the valve is of the ball type. In Fig. 8, the contact type valve is planar to planar.

In the various figures, the spring 13 is compressed by the cam 14 via a ball 15. Other means could also be used, e.g. a shoe that slides on the comb. The ball 15 is only an aid obvious to the person skilled in the art for transmitting the action of the cam 14 to the spring 13.

Furthermore, the spring 13 and the cam 14 could be replaced by any equivalent means which makes it possible to apply to the valve 11 m) 10 15 20 25 30 35 40 7 450 592 an counteracting force having specified properties.

In particular, pneumatic or oleopneumatic devices could be used. The cam and spring system is nevertheless preferable due to its simplicity.

Pig. Fig. 3 illustrates a comb profile suitable for the embodiments shown in Figs. 1 and 2. The raised portion of the cam, which corresponds to the counteracting force, occupies at least a portion of the zone corresponding to the suction phase and the lifting curve can be achieved in different ways.

In the example shown, the lifting curve is formed by a platform or ledge of constant height, but the invention is not limited to this arrangement. In fact, one can give the cam a shape so that the application of the spring 13 by means of the cam 14 becomes progressive.

In the case shown in Fig. 1, the cam 14 is fixed and wedged in its angular position relative to the pump body 20 by means of means 16.

In the case shown in Fig. 2, the cam 14 rotates together with the plate. It is wedged in its angular position by means of means 17.

In the case of Fig. 4, the cam 14 can be supported by the shaft Z1, which supports the cam 10 acting on the pistons. Its profile is illustrated in Fig. S. a.

Claims (3)

1. 45d 592. A hydraulic pump comprising at least one piston, each piston being associated with an outlet valve and a suction valve which is returned to the closed position by a return spring, characterized in that each suction valve (11) is arranged to be subjected to action of two opposing forces from two springs, namely a first which is from the return spring (12) and which acts on the valve in the closing direction, and a second which is from a second spring (13) and which acts on the valve in the opening direction. the force exerted by the second spring (13) varies as a function of the cycle of the pump, so that it is less than the force exerted by the first spring (12) during the discharge phase and is greater than the force exerted by the second spring (13). is exerted by the first spring (12) during at least a part of the suction phase in such a way that the suction valve only opens when the residual pressure in the dead chamber due to the start of the suction pipe of the piston has fallen below a predetermined value. Pump according to claim 1, characterized in that the variation of the force generated by the second spring (13) is obtained by means of a cam (14), against which said spring (13) abuts. Pump according to claim 2, characterized in that it comprises a plurality of pistons (1), which are parallel to the axis of the pump and arranged in a rotating cylinder (6) and which are engaged with the inclined surface on a non-rotating oblique plate (5), each spring (13) being assigned to an intake valve (11) abutting the cam (14) which is circular and fixed relative to the body of the pump. Pump according to claim 2, characterized in that it comprises a plurality of pistons (1), which are parallel to the axis of the pump and engage the inclined surface of a rotating oblique plate (8), the body of the pump (9) wherein the pistons (1) and the valves (II) are arranged are fixed and wherein the cam (14) is circular and fixedly connected to the shaft supporting the oblique plate (8) - 5. Pump according to claim 4, characterized in in that the cam (14) is supported by a shaft (14a) connected to the oblique plate by means of means which allow it to be displaced 180 ° in rose! 9 450 592 direction of inclination of the oblique plate (8). _ 6.. Pump according to claim 5, characterized in that the shaft (14a) is pivotally engaged in a bore (18) which is coaxial with the plate and in which a pin (19) projects, which pin penetrates into the shaft (14a) received , semicircular groove or shoulder (20), the pin (19) engaging one or the other of said end of said groove or shoulder (20) in accordance with the direction of rotation of the inclined plate, so that the cam (14) is displaced 1800 in the direction of rotation of the oblique plate. Pump according to claim 2, characterized in that it comprises a plurality of pistons (1) arranged radially in relation to the axis of the pump and in engagement with a cam (10), which is fixedly connected to the shaft, the cam (14 ) which abut against the springs (13) are likewise fixedly connected to said shaft. Pump according to one of Claims 1 to 7, characterized in that the cam (14) and the springs (13) are defined in such a way that each intake valve (11) is opened when the residual pressure of the liquid is less than 15 bar. . 9. A pump according to claim 8, characterized in that the opening of each valve (II) takes place at a residual pressure of the size 3 to 5 bar.