FR2497880A1 - GEAR PUMP - Google Patents

Abstract

It has an outer gear wheel (5) and, mounted eccentrically with respect thereto, an inner gear wheel (7), which gear wheels on one side mesh and on the opposite side are separated from one another by a filler piece (9a). Debouching in the two circumference sections located in between there are a feedline (10) and a discharge line (11). So as to use a gear pump of this type for low-viscosity liquids and high discharge pressures, the outer gear wheel (5) runs in a bush (6) which in the outlet zone of the feedline and discharge line (10, 11), respectively, has one passage orifice (12, 13) each, these having a smaller cross-section and being further apart in the circumferential direction than the outlets of the feed and discharge lines (10 and 11, respectively). In addition, the outer gear wheel (5), which is fashioned as a crown gear, and the pump casing (1) have arranged between them in an axial position a balancing disc. This has the pump fluid acting on it on both sides and serves to support the crown gear (5) axially with respect to the casing (1).

Description

 The present invention relates to a gear pump suitable in particular for low viscous liquids and high discharge pressures, of the type comprising an external toothed wheel mounted in rotation in the pump body and an internal toothed wheel mounted eccentrically in this body. which, on the one hand, meshes with the external toothed wheel and which, on its opposite side, is separated from it by a circular segment, of the suction and discharge conduits opening into the two zones located between these toothed wheels.

 There are many known embodiments of gear pumps having the technical characteristics described above. However, they are only very limited to the delivery of liquids with low viscosity and high delivery pressures.

Indeed, in such operating conditions, the inevitable clearances between the toothed wheels and the pump body lead to considerable leaks and, in particular, to the fact that the liquid to be pumped backs up from the delivery pipe towards the suction pipe. . This reflux is further facilitated by the fact that, in order to obtain good efficiency from the pump, it is necessary to make the suction and discharge conduits of the pump close to one another, so as to have, as active pumping area, as wide as possible at the periphery of the teeth.

 If such gear pumps are to be used for liquids with low viscosity or for high discharge pressures, another pump body must be used in which the suction and discharge lines are spaced apart. from the attti e, this eJUi makes it difficult to reflux the liquid to be pumped. However, this solution is very expensive and, moreover, it irreversibly reduces the efficiency of the pump.

 In view of the foregoing, the object of the present invention is to improve the gear pumps of the kind specified above, so that they are also suitable, if the user so desires, for liquids with low viscosity and pressures of high discharge, without the need to modify the foundry mold which is used for molding the pump body.

In particular, it must be possible to subsequently convert the known type of exi.slantfs gear pumps to adapt them to pumping liquids with low viscosity.

 According to the invention, this object is achieved by the fact that the external toothed wheel rotates inside a sleeve which is fixedly mounted in the body of the pump, which extends axially over the entire length of the teeth and , optionally, deys adjacent suction and discharge conduits, which projects axially on both sides and which, in the vicinity of each of the suction and discharge conduits, has a passage orifice for the liquid to be discharged, these orifices passage having a smaller section and a distance between them in the direction of the periphery greater than that of the mouths of the suction and discharge pipes.

 Thanks to these arrangements, the suction and delivery ports on the side of the external toothed wheel are located at a greater distance from each other than in the body of the pump. Slits of greater length are thus obtained between these suction and discharge orifices, which considerably reduces the reflux which is usually encountered in the case of liquids with low viscosity and high discharge pressures. To insert the sleeve, simply rotate or bore the internal bore of the original pump body over a few millimeters to provide the sleeve, in the radial direction, with the space which is necessary for its insertion. the position of the passage openings in the sleeve to lead to the suction and discharge conduits can be optimally adapted to the predetermined operating conditions. In particular, it is also possible, starting from pumps for liquids with low viscosity, in which the relatively small orifice openings are formed, to transform them afterwards into pumps for liquids viscous or at low discharge pressure, by simply introducing a sleeve whose passage orifices, as regards their dimensions and their position, are adapted to the outlets in the molded body of the suction and discharge conduits.

 It is therefore always possible to adjust the gear pump according to the invention so that it provides optimum efficiency as a function of the predetermined operating conditions.

 Finally, this sleeve also has the advantage that it can be made of a material different from that of the molded body of the pump, ei, in particular, a special bronze having anti-friction properties. Thanks to its better friction properties, it can, to a large extent, also serve as a bearing for the external toothed wheel, which relieves the bearing and prolongs the service life of the pump.

 Preferably, the sleeve is made in the form of a simple interchangeable element with axial insertion, so that, when the sidewall which serves as a cover for the pump body has been removed, it can be removed and replaced. by another suitable sleeve.

 In most embodiments of the gear pumps described above, the outer gear is made in the form of a gear. In this case, it is known that this ring rests by its rear front face on the pump body with the interposition of a balancing disc, the latter being mounted fixed and provided on its two faces with coaxial annular grooves which are interconnected by axial holes and which are traversed by the liquid to be pumped. This balancing disc serves to support the ring gear against the axial compression force exerted by the liquid to be pumped. In this case, it is particularly advantageous that the annular groove facing the gear ring is connected to the side. of the pumping by a radial groove made in the balancing disc, this groove extending towards the outside, and by an axial groove of the pump body so that with the two annular surfaces which it are radially adjacent. said annular groove constitutes a hydraulic bearing surface corresponding to the active surface of the ring gear. This arrangement ensures that wear between the rotating ring gear and the fixed balancing disc is reduced to a minimum, which prolongs the life of this disc.

 In addition, it is possible to provide, inside the annular groove facing the ring gear, an additional annular groove which leads the reflux of the liquid to be pumped towards the bearings of the shaft of the ring gear through a groove radial extending outward.

 According to another characteristic of the invention, it is advantageous that the annular groove of the balancing disc facing the pump body has a hydraulic bearing surface which exceeds by 10% that present on the opposite face of the balancing disc . This guarantees an optimal balance of clearances and forces between the moving parts of the pump. In known manner, the annular groove specified above can be sealed relative to the body of the pump by means of internal and internal O-rings.

 Finally, it is advantageous that the balancing disc is surrounded by the sleeve. In fact, a permanent and well-defined stop surface is thus obtained for the sleeve which is introduced axially into the body of the pump.

The description which follows and which has no limiting character, will make it possible to understand clearly how the present invention can be put into practice. It should be read in conjunction with the accompanying drawings, among which
- Figure 1 shows an axial sectional view of the gear pump according to the invention
- Figure 2 shows a cross-sectional view taken along the line -Il-Il of Figure 1
- Figure 3 is an elevational view of the sleeve specified above
- Figure 4 shows a top view of the balancing disc according to the invention
- Figure 5 shows an enlarged sectional view taken along line VV of Figure 4.

 In a pump body 1, a shaft 4 is mounted on needle bearings 2 and 3, t this shaft is rotated by its free end. At its other end, it carries an external toothed wheel 5 which has the shape of a toothed crown. This toothed wheel 5 rotates in a cylindrical sleeve 6 which is housed in a coaxial bore of the pump body. Outside the external toothed wheel 5, but eccentric with respect to it, is housed an internal toothed wheel which meshes by an upper zone with the external toothed wheel 5. 1, n internal toothed wheel 7 is mounted cn rotation on a shaft 8 which is fixed, for its part, on a side 9 serving lte cover and screwed on the pump body .

FIG. 2 shows the eccentric arrangement of the external and internal toothed wheels 7. It also shows that a crescent-shaped segment 9a, produced in one piece with the cover 9, is mounted in the space left free by the eccentricity of the gear wheels. Thus are located closed chambers above and below the circular segment 9a, chambers in which the liquid
to be driven back is moved from one side to the other of the interior space of the pump, according to the direction of rotation of the toothed wheels 5 and 7.

 The suction and discharge conduits which open on both sides into the interior of the pump are designated respectively by the references 10 and 11. Their sections are shown in FIG. 1 by dashed lines. The arrangement and dimensions of the orifices of the suction and delivery conduits in the molded body i of the pump are chosen, in known manner, so that they extend over an extended region of the periphery of the toothed wheel exterior 5, whereby the pump is characterized by high efficiency. According to the invention, however, the external toothed wheel is mounted, not directly in the molded body 1, but in the cylindrical sleeve 6.

The latter is produced in the form of an insertion element which is introduced axially and which is easy to interchange, and it is slab-mounted with the movable body without being able to rotate. On its opposite sides, it has through orifices 12 and 13 which lead respectively to the suction and discharge condtlits 10 and 11. The angular position and the dimensions of these passage orifices are calculated such that the leakage liquid which flows back from the discharge side to the side of suction because of the pressure difference between the pump connections, must travel along the sleeve 6, a slot of significantly greater length than if the outer gear 5 turned directly in the molded body or the distance between the side the suction side and the discharge side is much weaker.

 The sleeve 6 therefore makes it possible to .1 reversibly equip e11grellage pumps provided with the original body which are calculated to provide a high flow rate, so that they are also suitable for liquids with low viscosity and high discharge pressures. .

 Figure 3 shows the sleeve 6 isolated from the rest of the device. We recognize in this figure the passage orifice 12 whose width is adapted to the axial extent of the teeth. To allow flow as free as possible from losses, the two passage openings are widened upwards by milling on the side of the external face of the sleeve 6.

 Figures 4 and 5 show a balancing disc 14 which ess disposed between the rear front surface of the outer gear 5 and the body 1 of the pump. This disc has, on its face which is shown in FIG. 4 and which faces the toothed wheel 5, two annular grooves 15 and 16, the outer annular groove 15 and the two adjacent annular surfaces 14a and 14b then serving to generate a hydraulic bearing force which supports the external toothed wheel 5 against the compression pressure of the liquid which prevails in the teeth. For this, the annular groove 15 has a groove 15a which extends radially, which opens into a axial groove of the sleeve 6, which is not shown in the figures in detail, and which is supplied from there, liquid subjected to the discharge pressure.

 In addition, the balancing disc 14 has a hole 17 in the annular groove 15 leading to a rear annular groove 18 which can be distinguished in FIG. 5. I, the effective hydraulic surface of this annular groove 18 is calculated such that so that it exceeds by 10% the bearing surface which is constituted by the annular groove 15 and by the two adjacent annular surfaces 14a and 14b, and which is present on the oppoMedu side of the disc. The external toothed wheel 5 is then pushed towards the internal toothed wheel 7 by about 10% of the compression force, and thus is compensated for the axial play due to the compression force which exists between the two dCtite wheels - ('S. between the balancing disc 14 and the external toothed wheel 5, and also between the internal toothed wheel 7 (t I e cover 9. The balancing disc also compensates for the axial wear which may occur.

 As shown in FIG. 1, the balancing disc 14 is mounted inside the sleeve 6 and is passed in its center on the shaft. To prevent it from turning, it is fixed to the body of the pump by a stud 19.

 To summarize, the advantage obtained thanks to the invention consists in the fact that a pump can be optimally adapted to the values of the pressure and the viscosity of the liquid to be pumped, by the simple installation of a sleeve having appropriately arranged through holes, without the need to modify the construction of the molded body. The balancing disc mounted inside the sleeve axially relieves the external gear of the pump and its bearings, which increases the service life of the pump. In addition, the 10% axial thrust exerted by the external toothed wheel on the internal toothed wheel reduces the axial play which would occur in its absence, which reduces leakage losses, even in the case of very weak liquids. viscous, and therefore allows working at high pressures.

Claims (3)

- CLAIMS 1. Gear pump, particularly suitable for liquids with low viscosity and high discharge pressures, of the type comprising an external toothed wheel mounted in rotation in the pump body and an internal toothed wheel mounted eccentrically in this body which, d 'one side, meshes with the external toothed wheel, and, on its opposite side, is separated from it by a circular segment, suction and discharge conduits opening into the two zones located between these toothed wheels, pump characterized in that the external toothed wheel (5) rotates inside a sleeve (6) which is fixedly mounted in the body (1) of the pump, which extends axially over the entire length of the teeth and, optionally, adjuvant suction and discharge conduits (10, 11), which projects axially on both sides and which, in the vicinity of each of the suction and discharge conduits (10, 11), has a passage orifice (12, 13) for the liquid to r flow, these passage openings (12, 13) having a smaller section and a distance between them in the direction of the periphery greater than those of the mouths of the suction and discharge conduits (10, 11). 2. Gear pump according to claim 1, characterized in that the sleeve (6) is produced in the form of an interchangeable insertion element. 3. Gear pump according to any one of claims 1 and 2, characterized in that the sleeve (G) is made of anti-friction metal.