EP0661454A1 - Internal gear pump - Google Patents

Abstract

In connection with an internal gear pump with internal gear (6) and a pinion (5) meshing with the internal gear (6), the internal gear (6) having radial apertures (17) for the medium to be pumped, and one sealing element (30) each, radially movable in a profiled groove (34) of corresponding design, being inserted into the tooth tips (14) of the internal gear (6) or into the tooth tips (13) of the pinion (5), which sealing element (30) can slide on the opposite tooth tip of the pinion (5) or the internal gear (6), it is proposed to adapt the head shape of the sealing element (30) and the base shape of the tooth gaps of the internal gear (6) or the pinion (5) to one another in such a way that the sealing between the pressure and suction space is verified by the sealing element (30) in the area of the dead centre. <IMAGE>

Description

The invention relates to a sickle-free internal gear pump for generating high pressure with the features specified in the preamble of claim 1. A pump of this type is known as a special embodiment from DE 41 04 397 A1.

Internal gear pumps of this known type generally have an internally toothed ring gear with which an externally toothed pinion meshes, that is to say is in driving engagement. This pinion has one tooth less than the ring gear. The pinion is so eccentric to the ring gear that the outside of a tooth head on the pinion comes into contact with the inside of a tooth head on the ring gear. The generic gear pumps also have a suction connection in the area in which the teeth disengage when the pinion rotates. Accordingly, they show a pressure connection on the side opposite the suction connection, where the teeth come back into engagement. The delivery of the pressure medium into or out of the interior of the ring gear is ensured by essentially radial openings. These breakthroughs start from the outer surface of the ring gear and open into the tooth base.

The circumference of the ring gear thus divides into a suction chamber, in which the pressure medium from the suction connection via the Breakthroughs is sucked in, and a pressure chamber in which the pressure medium from the inner region of the ring gear is pressed outwards through the openings. These two areas are separated in the tooth mesh by the so-called dead center of the toothing.

In the sickle-free internal gear pump known from DE 41 04 397 A1, the flank seal of a pinion tooth with the respective ring gear tooth ends well before the tooth dead center due to the low number of teeth. The area from the end point of the flank seal to the dead center is part of the pressure chamber, in which pressure medium is conveyed. This remaining delivery rate should also be delivered to the pressure chamber, otherwise the specific delivery volume will be considerably smaller (compared to the theoretical q).

The then missing seal on the tooth flank causes a deterioration in the volumetric efficiency.

The present invention is based on the problem of specifying a sickle-free internal gear pump with involute toothing (i.e. with a large operating pressure angle) in which the theoretical, specific delivery volume is conveyed without the volumetric efficiency losses being recorded.

This object is achieved by a sickle-free internal gear pump with the features specified in claim 1. Advantageous developments of the invention are presented in the subclaims.

According to the invention, the sealing element is designed with respect to its head shape so that it cooperates sealingly with the foot shape of the tooth space of the ring gear or the pinion. This sealing effect is due to the sealing element in connection with the base of the tooth space given in the area of the dead space. In addition to this sealing effect, there is also the generic sealing effect due to the flanks lying against one another, so that the pump according to the invention has an enlarged area of the pressure chamber with a good sealing effect. This expansion of the sealing action range creates an improvement in the pump efficiency, since according to the invention now more pressure medium with a good sealing action comes from the pressure chamber into the pressure connection.

The improvement in efficiency is achieved without an additional increase in production costs, since each of the elements used in connection with the overall construction has already been used in a similar manner in the prior art.

According to a further embodiment of the invention, the pressure medium is guided to the rear of the sealing elements via axial grooves.

These axial grooves are arranged in the housing part in which the pinion is rotatably mounted or in the pump version with axial compensation in the axial disks.

These axial grooves ensure that the radial sealing elements are pressed against the tooth base of the respective tooth gap.

Fig. 1

zeigt in teilweise geschnittener Längsansicht ein Ausführungsbeispiel der Innenzahnradpumpe;

Fig. 2

zeigt in teilweise geschnittener Längsansicht ein Ausführungsbeispiel der Innenzahnradpumpe mit einer Axialscheibe zum Ausgleich des Axialspiels;

Fig. 3

zeigt in einem Querschnitt durch die Innenzahnradpumpe den Bereich des Ritzels und des Hohlrades;

Fig. 4

zeigt in einer Detailansicht die Verzahnung in dem Bereich des Totpunktes.

An embodiment is shown in the drawings and will be described in more detail below.

Fig. 1

shows a partially sectioned longitudinal view of an embodiment of the internal gear pump;

Fig. 2

shows a partially sectioned longitudinal view of an embodiment of the internal gear pump with an axial disk to compensate for the axial play;

Fig. 3

shows in a cross section through the internal gear pump the area of the pinion and the ring gear;

Fig. 4

shows in a detailed view the teeth in the area of the dead center.

Figures 1, 2 and 3 show the sickle-free internal gear pump in a longitudinal section and the arrangement and mode of operation of the gears in a cross section.

The internal gear pump shows a housing which consists of the housing middle part 1 and the housing side parts 2, 3. The two housing side parts 2, 3 sealingly comprise the housing middle part 1, in the interior of which the internally toothed ring gear 6 with an externally toothed pinion 5 is arranged. The pinion 5 is fastened to a drive shaft 4 and drives it via its toothing 12, which engages in the toothing 12 of the ring gear. The pinion 5 and the ring gear 6 are not arranged coaxially, but eccentrically to one another; furthermore, the pinion 5 has one tooth less than the ring gear 6, so that in each case the outside of a tooth head 13 on the pinion 5 comes into contact with the inside of a tooth head 14 on the ring gear. A suction connection 7 can also be seen in the middle part 1 of the housing in the region in which the teeth of the pinion 5 and the ring gear 6 disengage when rotated in the direction of the arrow X. On the side of the housing middle part 1 opposite the suction connection 7 there is a pressure connection 10 which is arranged in the region in which the teeth of the pinion 5 and the ring gear 6 come into engagement again. The inflow of the pump medium from the suction connection 7 to the interior of the pump and from there to the pressure connection 10 takes place through openings 17. These openings 17 start from the outer surface of the ring gear 6 and open into the tooth base of a tooth space of the ring gear 6.

The flow of the pump medium is indicated by the arrows Y shown. The housing parts 2, 3 have axial grooves 40 in the area of the interlocking teeth 13, 14.

In pumps - of the type known from DE-OS 42 08 767.8 - which have an axial disk to compensate for the axial play (see FIG. 2), the axial control groove 40 'is located in the axial disk 41.

FIG. 3 shows the dead center (TP) of the toothing (12, 12), which describes the end of the penetration of the pinion toothing into the hollow toothing. Due to the small number of teeth, here 11 teeth of pinion 5, compared to 12 teeth of ring gear 12, there is an operating pressure angle of the involute toothing of over 50 °, which is indicated by the so-called engagement line E.

FIG. 4 shows a section of FIG. 3, in which the tooth heads 13, 14 engage in the tooth gaps of the pinion 5 or the ring gear 6. The tooth heads 14 of the ring gear 6 have a mushroom-shaped sealing element, which is matched with respect to its cross-sectional shape to the foot shape of the tooth space of the pinion 5. The mushroom-shaped sealing element 30 is arranged in a radial profile groove 34 so that it can be moved radially displaceably over a certain margin. The head of the sealing element 30 is convex and, in conjunction with the slightly concave foot shape of the tooth gap, ensures a good sealing effect. This sealing effect of the sealing element 30 with the foot of the tooth gap occurs in addition to the flank seal of the teeth 13 of the pinion 5 with respect to the teeth 14 of the ring gear 6 during the advance.
The area in which the flank seal is effective, viewed in the direction of rotation X, ends before the dead center TP, ie within the pressure area. In this part of the pressure range in which the flank seal is not effective only the sealing effect through the sealing element 30 in connection with the foot of the tooth gap is effective. Since this area can now be used according to the invention, the delivery volume of the pump medium and thus the efficiency of the pump is increased.

An axial groove 40 in the housing part 2 or 3, which is acted upon by pump medium, is also schematically indicated in FIG. 4, via which a defined pressing of the sealing element 30 against the base of the tooth space of the pinion 5 can be achieved. (This axial groove 40, 40 'is also indicated in Figure 1, 2.)

As in FIG. 3, the dead center TP of the toothing is shown in FIG. 4 with the operating pressure angle defined by the line of engagement E of over 50 °.

Even if the combination of sealing element 30 in the tooth head 14 of the ring gear 6 with the foot of the tooth space of the pinion 5 was disclosed in the foregoing with reference to FIG. 4, correspondingly equivalent combinations are also via sealing elements in the tooth heads 13 of the pinion 5 in connection with the foot the tooth gap of the ring gear 6 possible.

Claims (2)

Sickle-free internal gear pump with internally toothed ring gear (6) and a pinion (5) meshing with the ring gear (6), which is rotatably mounted in a jointly mounted housing part (1), the axial extent of which is the width of the toothing (12) of the ring gear (6) and of the pinion (5) and which has a suction connection (7) and a pressure connection (10), the ring gear (6) having radial openings (17) for the medium to be pumped, and in the tooth tips (14) of the ring gear (6) or in the tooth heads (13) of the pinion (5) each a radially movable sealing element (30) is inserted in a correspondingly designed profile groove (34), which on the opposite tooth head of the pinion (5) or the ring gear (6 ) can slide,
characterized,
that the head shape of the sealing element (30) and the foot shape of the tooth space of the ring gear (6) or the pinion (5) are coordinated with one another in such a way that the seal between the pressure chamber and the suction chamber is verified by the sealing element (30) in the region of the dead center becomes. Sickle-free internal gear pump according to claim 1,
characterized,
that the housing part or parts (2, 3), which jointly support the ring gear (6) and the pinion (5), have an axial groove (40) in the area of the dead center, through which the pressing of the sealing element (30) on the tooth base is controlled.

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