FI82295B - HYDRAULIC MECHANISM, MOTOR ELLER PUMP. - Google Patents

Description

1 82295

Hydraulic mechanism, motor or pump

The present invention relates to a hydraulic mechanism provided with a level distributor and a distribution flange.

In known pressure medium motors, in particular hydraulic motors, level dividers are used to distribute the fluid to successive cylinders and sometimes manifold flanges. The latter are mainly used as chapter numbers, by means of which the original operating characteristics of the mechanism can be maintained even in long-term use.

The invention relates to such a mechanism, namely a hydraulic mechanism, motor or pump, comprising: - a cylinder block with an end face forming a connection outside, - a plurality of cylinders formed in the cylinder block block, each of which slides a piston, each the cylinder is connected to the interface of the cylinder block by at least one cylinder channel which opens to this interface through the cylinder opening, - a cam ring with respect to which the cylinder block is arranged to rotate about an axis of rotation and against the surface of which the pistons rest and - a plane divider which is non-targetingly connected to the cam ring and has a contact surface to which as many pairs of openings open as there are pairs of ramps in the cam ring, the first opening of the pair of openings being arranged to communicate with a first chamber having pa the second opening of the orifice pair can be brought into contact with the second non-pressurized chamber, and the orifices of the orifice pairs follow each other at the interface of the planar divider so that the second orifice of the pair is located between the first orifice of this pair and the first orifice of the next pair. wherein as the cylinder block rotates relative to the cam ring (and plane divider), each cylinder port first communicates with the first port of the orifice, then isolated from the first orifice of the orifice located between the first and second orifices, and finally with the second orifice of the orifice pair; - the interface surfaces of the divider are planar, perpendicular to the axis of rotation and in direct contact with each other, and the cylinder openings and the first and second openings of the divider open between two concentric circles centered on the axis of rotation.

According to the invention, the mechanism is recommended to be equipped with one or more distribution flanges, but is not considered necessary or obligatory.

Even if one or more distribution flanges are used, the object of the invention is quite different from trying to preserve the original operating characteristics: to provide, with or without distribution flanges, a mechanism which is as small as possible in transverse dimensions (in a plane perpendicular to the axis of rotation of the rotor). The construction of such a mechanism is complicated in particular by the fact that the opening 25 of any cylinder must not overlap even partially with the two successive openings of the level divider, otherwise the pressure fluid would return from the second opening of the level divider to the unpressurized chamber without working in the corresponding cylinder. In order to achieve a certain flow, the cross-sectional area of each orifice must be greater than a certain minimum value. According to the state of the art, the minimum distance between the adjacent edges of two successive openings in the level divider had to be greater than the corresponding dimension of the opening in the cylinder in order for this to fit between said two openings in the level divider.

With the solution according to the invention, this minimum of 3 82295 can be reduced and it is possible to manufacture mechanisms which are smaller in size than hitherto.

To achieve this object, the invention is characterized in that the cylinder openings are complementary in shape with respect to the first and second openings of the plane divider and the area of the cylinder opening is substantially equal to the area between said two circles on the one hand and the first and second between the orifices so that the cylinder orifice can be sequentially contacted with the first orifice of the orifice pair of the level divider within the operating clearance, isolate the orifice pair from the first and second orifices, and contact the second orifice 15 of the orifice pair.

Another embodiment of the invention relates to a mechanism, motor or pump comprising: - a cylinder block with an end face connecting to the outside, 20 - a plurality of cylinders formed in the cylinder block, each of which slides a piston, each cylinder being connected to the cylinder block. a cam ring with at least one cylinder channel opening to this interface through the cylinder bore, 25 - a cam ring with respect to which the cylinder block is arranged to rotate about an axis of rotation and against the surface of which the pistons rest and comprising a plurality of inclined ramps a plane divider non-rotatably connected to the cam ring and having a contact surface to which as many pairs of openings open as the cam ring has pairs of ramps, the first opening of the pair of openings being arranged to communicate with a first chamber having 35 pressurized flows the second orifice 4 82295 of the orifice pair can be brought into contact with the second non-pressurized chamber, and the orifices of the orifice pairs follow each other at the interface of the planar divider so that the second orifice of the orifice is between the first 5 orifices of this pair and the first orifice of the next pair, wherein as the cylinder block rotates relative to the cam ring (and plane divider), each cylinder port first communicates with the first port of the orifice, then isolated from the first port and the second port of the pair of ports between the first and second ports and finally with the second port of the pair of ports, located between the cylinder block and the level divider and connected to one of these parts (cylinder block and level divider) is provided with two contact surfaces, one surface of which is opposite the interface of the part to which the first manifold is connected and the other surface is planarly perpendicular to the axis of rotation and in contact with a planar surface attached to one of said two parts 20 and likewise perpendicular to the axis of rotation, whereby the so-called through-openings, some of which correspond to and are in permanent communication with the cylinder openings so that one through-opening is in each case connected to one cylinder opening, and the other 25 correspond to the first and second openings of the plane divider and are in permanent communication with each of the first and second through-openings to the first and second apertures of the planar divider, and all through holes open between two concentric circles centered on the axis of rotation.

According to the invention, in this mechanism, the passages associated with the cylinder block are complementary to the first and second passages associated with the plane divider, and the area of the passage 35 associated with the cylinder block is substantially equal to the area between the two circles and between the first and second passage openings of the pair of passage openings so that the passage opening associated with the cylinder block can be sequentially connected to the first passage opening associated with the level divider within the operating clearance 5, isolate the passage opening associated with the level divider

The most significant advantage achieved by the solutions according to the invention is that the centers of the cylinder openings can be placed on a circle with a smaller radius than in the known mechanisms of the corresponding circles, and thus even smaller, lighter and cheaper mechanisms can be produced.

The invention will be better understood from the following description with reference to the accompanying drawings, in which:

Figure 1 is a longitudinal section of a hydraulic motor according to a first embodiment of the invention.

Figure 2 is a partial section along the line II-II in Figure 1.

Figures 3 and 4 are sections along lines III and IV in Figure 1.

Fig. 5 is a longitudinal section similar to Fig. 1 of a hydraulic motor according to a second embodiment of the invention.

Figures 6 and 7 are sections along lines VI-VI and VII-VII in Figure 5.

Fig. 8 is a longitudinal section of a hydraulic motor according to a third embodiment of the invention.

Figures 9, 10 and 11 are sections along lines IX, X and XI in Figure 8.

Fig. 12 is a longitudinal section of a hydraulic motor according to a fourth embodiment 35 of the invention.

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Figures 13, 14 and 15 are sections along lines XIII, XIV and XV in Figure 12.

Figures 16 and 21 are longitudinal sections of a hydraulic motor 5 according to a fifth embodiment of the invention.

Figures 17, 18, 19 and 20 are sections along lines XVII, XVIII, XIX and XX in Figure 16, and it can be seen that the section lines of the parts included in the different sectional views have been omitted to make the figures clearer.

The invention is particularly applicable to the hydraulic mechanisms described in FR patents 2,504,987 and 2,533,965.

All the embodiments 15 described and shown in Figures 1-20 relate to a hydraulic motor comprising: - a two-part housing 1, - an intermediate ring 2 placed between the two parts of the housing 1, fixed to these two parts by screws 3 and supporting a corrugated cam ring 4 with each cam 20 comprises two inclined ramps, one corresponding to the supply of liquid to the engine and the other to the discharge of liquid from the engine, - an engine output shaft 5 arranged to rotate by means of tapered roller bearings 6 relative to the housing 1 and the axis of symmetry 7 and provided with keyways 8, - cylinder block 9 provided with grooves 10 corresponding to the keyway 8 of the shaft 5 and connected to these grooves 8, the cylinder block 9 being arranged to rotate relative to the housing 1 about the axis of symmetry 7, - cylinders 11 formed in the cylinder block 9 and arranged radially with respect to the axis of symmetry 7, - pistons 12 arranged 1 slide in each cylinder 11, 7 82295 - rollers 13 arranged in housings 14 formed in the pistons 12, one roller in each piston, and arranged to rotate about the pin 15 in the direction of the axis of symmetry 7 and in rolling contact with the cam ring 4, 5 - a planar surface 16 which is formed in the cylinder block 9 and is perpendicular to the axis of symmetry 7, - a plane divider 17 with a plane surface 18 perpendicular to the axis of symmetry 7, two axially symmetrical grooves 19 and 20 (axis 7), a plurality of channel pairs 21, 22 formed in the level divider 17 and connecting the grooves 19 and 20 to the planar surface 18 to which they open through the openings 23 and 24, each opening 23 being located between the two openings 24 and vice versa and one 23 of them corresponding to one ramp of the cam ring and the other 24 a second ramp of the cam, and means 25 for keeping the level divider 17 connected to the housing 1, - channels 26, 27 formed in the housing 1, connecting grooves 19, 20 in the connections 28, 29, which are also formed in the housing 1 and to which external lines 30, 31 can be connected for introducing and removing the pressurized fluid, - a plurality of channels 32 formed in the cylinder block 9 and each connecting the cylinder 11 to the cylinder. 25 to the planar surface 16 of the blade block, to which they open through the openings 33.

In the embodiment according to Figures 1-4, the plane surface 18 of the plane divider 17 rests on the plane surface 16 of the cylinder block 9. All openings 33 of the surface 16 are round and identical and are located on the same circle and thus flank two concentric circles 34 (outer circle) and 35 (inner circle). circle) and located at regular intervals in the circumferential direction. The openings 23 and 24 in the surface 18 of the plane divider 17 are also located at regular intervals in the circumferential direction and are in the shape of lunar crescents flanking two identical central circles, outer 34a and inner 35a, having a radius equal to circles 34 and 35. Each lunar aperture 23 is located at a distance from the next opening 24 such that between the two successive openings 5 an area slightly larger than the opening 33 of the surface 16 remains, so that each opening 33 of the cylinder block 9 with the opening 23, is then located between the opening 23 and the next opening 24 10, isolated therefrom, and finally comes into contact only with said opening 24, etc.

Furthermore, it is easy to understand that if in the described example the apertures 33 are round and the apertures 23 and 24 are crescent-shaped, the inventive idea is to make the apertures 15 23 and 24 and the apertures 33 complementary in shape so that the aperture 33 between the aperture 23 and the aperture 24 can at the same time be insulated from both openings and cover as completely as possible the space between the circles 34 and 35 (or 34a and 35a) and said two openings 23, 24 so that the hydraulic connection can be satisfactorily connected between the opening 33 and the opening 23 within the additional clearance, then isolates the opening 33 from said two openings 23 and 24 and finally communicates this opening 33 with the opening 24.

Figures 5, 6 and 7 show another embodiment in which the plane surface 18 of the plane divider 17 also rests directly on the plane surface 16 of the cylinder block 9 and the openings 23 and 24 of the surface 18 are circular and the openings 33 of the surface 16 are crescent-shaped and complementary to the circular openings 23 and 30 24. form, as described above.

The circular shape of the hole is often the result of it being made by drilling. A crescent-shaped hole is less common and is often made into a massive body by casting.

In the case of the embodiment 990295 described below, round holes can be used in solid pieces (level divider 17 and cylinder block 16) and the holes can be made simply by drilling into possibly forged workpieces, and this is possible by means of complementary pieces 5 (one or two) placed on said surfaces. 16 and 18 and provided with crescent-shaped holes as described above.

In the embodiment according to Figures 8-11, a complementary part, a manifold 36, is rotatably connected to the level distributor 17. The level distributor 17 and the distributor flange 36 are non-rotatably connected to the housing 1 by means of a coupling member 25 as disclosed in FR Patent 2,533,965. The surfaces 16 and 18 of the parts 9 and 17 are planar and perpendicular to the axis 7 and the distribution flange 36 consists of a thin (e.g. 3 mm) body which also has two planar surfaces 37, 38 which are perpendicular to the axis 7. The planar surface 37 rests against the planar surface 16 of the cylinder block 9 with respect to which it can slide, and the planar surface 38 rests on the planar surface 18 of the divider. and are located on these holes 23, 24 without completely covering them (cf. 25 Fig. 11). In addition, the shape of these holes 39, 40 is complementary to the holes 33 of the surface 16 of the cylinder block 9, the adjective "complementary" having the same meaning as shown above in connection with Figures 3 and 4. The holes 39, 40 are located between two circles 34b, 35b 30, the center of which is on the axis 7 and whose radii are equal to those of the circles 34, 35.

A variation of the embodiment according to Figures 8-11 is shown in Figures 12 to 15. In this embodiment, the manifold flange 43 is fastened with screws 41 to the rotor 35 together with the cylinder block 9 and the level distributor is fixed to the housing 1 mm) from a body with two planar surfaces 44, 45 perpendicular to the axis 7, which rest on the surfaces 16 5 and 18 of the cylinder block 9 and the plane divider 17. This manifold flange 43 has as many through holes 42 as the cylinder block 9 has openings 33. Holes 42 correspond to the openings 33 located on top of them but not completely covering them (cf. Fig. 13) and are located between two circles 34c, 35c with radii 10 of the same size as the circles 34, 35, and the holes 42 are moon-shaped and "complementary" to the apertures of the divider 17 23, 24 (cf. Fig. 15).

The embodiment of Figures 16 to 21 includes, on the one hand, the solution according to Figures 8 to 11 and, on the other hand, the solution according to Figures 12 to 15, using two manifold flanges: a manifold 36 similar to Figure 10 and attached (25) to the plane divider 17. , and a manifold 43 connected (41) to rotate with the cylinder block 9. These manifolds are 20 as described above. The only difference is that the planar surface 37 of the manifold flange 36 rests on the planar surface 45 of the manifold flange 43. The holes 39, 40 of the manifold flanges 36 and 42 are further trapezoidal and "complementary" in shape (cf. Fig. 19). Thus, in the embodiment shown in Figures 16 to 20, the following solution is used, which will be repeated in the following: 9 on the round openings 33 without completely covering them (Fig. 17), - the plane surface 38 of the dividing flange 36 (fixed (25) to the level divider 17) rests on the plane surface 18 of this level divider 17 and the holes 39, 40 of this divider flange 36 are located on the level divider 17 covering the round openings 23, 24 without covering them in their entirety (Fig. 20), - the planar surface 37 of the manifold 36 rests on the planar surface 45 of the manifold 43, - the trapezoidal shape of the holes 42 of the manifold 43 is ).

In the various embodiments shown, the manifold flanges 36 and 43 are thin pieces in which the holes can be formed simply and inexpensively, although these holes are unusually shaped (crescents with two concavities, or substantially trapezoidal), and can be made by laser cutting or stamping.

In the illustrated embodiments, the various surfaces in contact with each other are planar and perpendicular to the axis 7: surface 16 of cylinder block 9, surfaces 37 and 38 of manifold 36, surfaces 44 and 45 of manifold 43, and surface 18 of plane divider 17. This feature is important in sliding surfaces (wheels) with respect to each other, such as: - surfaces 16 and 18 in the embodiments shown in Figures 1 to 4 and Figures 5 to 20, - surfaces 16 and 37 in the embodiment shown in Figures 8-11 and surfaces 45 and 18 in the embodiment shown in Figures 12 to 14, - surfaces 37 and 45 in the embodiment 25-21 shown in Figures 16-21.

Manifolds are easy to make from thin metal plate (on the order of 2 to 5 mm), as mentioned above, so when making these manifolds from metal plates with parallel surfaces, even those surfaces 30 which do not have to be planar and perpendicular to axis 7 are also planar and perpendicular against this axis, although this is not essential for operation.

However, these other surfaces can be of any shape, as long as they are complementary on the abutting surfaces.

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The following surfaces attached to each other can thus be of arbitrary shape as long as they are complementary to provide a tight connection: the surface 38 of the manifold flange 36 and the surface 36 5 of the divider 17 in the embodiments shown in Figures 8-11 and 16-21, the surface 16 of the cylinder block 9 in the embodiments shown in Figures 12 to 15 and Figures 16 to 21.

10 The described embodiments provide two types of benefits.

First, due to the "complementary" shape of the openings that can be sequentially connected to each other and then insulated from each other, such as the cylinder block openings 33 and the level divider openings 23, 24 in the embodiment of Figures 1-4, there are circles 34, 35 of a certain diameter. it is possible to place more openings 23, 24 in the shape of a constricted crescent in the middle than if these openings 23, 20 24 were round and, of course, of the same cross-section as the crescents, so that the flow rate in these embodiments is the same. It is also possible that the diameters of the circles 34, 35 are smaller with a certain number of pairs of openings 23, 24 (and the same number of cams in the cam ring 4) when the crescent-shaped openings are used than if the openings are round. In other words, the mechanism according to the invention can be made smaller, lighter and cheaper than those previously known.

Second, it has been found above that lunar shards are often easier to make in a thin than in a solid body, so that by using thin dividing flanges 36, 43 it is possible to manufacture the mechanisms according to the invention at low cost.

35 The use of manifold flanges provides another added benefit of the i3 82295: it is easier to achieve tight contact between surfaces with thin, slightly deformable parts than with solid parts.

The invention is not limited to the embodiments shown, but on the contrary covers all modifications which may be made without departing from the scope or spirit of the invention.

Claims (3)

A hydraulic mechanism, motor or pump, comprising: 5. a cylinder block (9) with an end face (16) connecting to the outside, - a plurality of cylinders (11) formed in the cylinder block, each of which slides a piston (12); ), each cylinder being connected to the interface of the cylinder block 10 by at least one cylinder channel (32) opening into this interface through the cylinder opening (33), - a cam ring (4) with respect to which the cylinder block is arranged to rotate about an axis of rotation (7) against the pistons (13) and comprising a plurality of inclined ramps, one after the other in pairs of ramps, - a level divider (17) non-rotatably connected (25) to the cam ring and having a contact surface 20 (18) which opens as many a pair of openings (23, 24) as the cam ring has pairs of ramps, the first opening of the pair of openings (23, 24) being arranged to communicate with the first n chamber (30) with pressurized fluid, and the second orifice 25 (24) of the orifice pair can be contacted with the second non-pressurized second chamber (31), and the orifices of the orifice pairs (23, 24) follow each other in the plane divider. (17) at the interface (18) such that the second aperture (24) of the pair of apertures is located between the first aperture (23) of this pair and the first aperture (23) of the next pair, wherein each cylinder blade aperture rotates relative to the cam ring (and plane divider). (33) first communicates with the first aperture (23) of the orifice pair, then insulated from the first orifice (23) and the second orifice (24) of the orifice pair located between the first 35 and second orifices, and finally with the second orifice (24) of the orifice pair 1582295, and the cylinder block ( 9) and the contact surfaces (16, 18) of the plane divider (17) are further planar, perpendicular to the axis of rotation (7) and in direct contact with each other, and the cylinder openings (33) and The first (23) and second (24) openings of the level divider (17) open in two concentric circles (34, 35); (34a, 35a) centered on the axis of rotation (7), characterized in that the cylinder openings (33) are complementary in shape with respect to the first 10 (23) and second (24) openings of the level divider (17) and the cylinder opening has a substantially equal surface area. larger than the area between said two circles (34, 35) on the one hand and between the first (23) and second openings (24) of the aperture pair (17) on the other hand so that the cylinder opening can be successively brought into contact with the first aperture pair opening within 15 operating clearances, isolates the pair of openings from the first and second openings and communicates with the second opening of the pair of openings of the level divider. A mechanism, motor or pump comprising: 20. a cylinder block (9) having an end face (16) connecting to the outside, - a plurality of cylinders (11) formed in the cylinder block, each of which slides a piston (12) , each cylinder being connected to the contact surface of the cylinder block by at least one cylinder channel (32) which opens to this contact via the cylinder opening (33), - a cam ring (4) with respect to which the cylinder block is arranged to rotate about the axis of rotation (7) the pistons being supported (13) and comprising a plurality of inclined ramps following each other in pairs of ramps, - a level divider (17) non-rotatably connected (25) to the cam ring and having a contact surface (18) 35 with an equal number of openings (23); 24) as the cam i 82295 has pairs of ramps, the first opening of the pair of openings (23, 24) being arranged to be connected to the first n with a chamber (30) with a pressurized fluid, and the second opening (24) 5 of the orifice pair can be brought into contact with the second non-pressurized second chamber (31), and the orifices of the orifice pairs (23, 24) follow each other in a level divider. (17) at the interface (18) such that the second aperture (24) of the pair of apertures is located between the first aperture (23) of this pair and the first aperture (23) of the next pair 10, each cylinder blade opening rotating relative to the cam ring (and plane divider) (33) first communicates with the first opening (23) of the pair of openings, then isolated from the first opening (23) and the second opening (24) of the pair of openings located between the first 15 and second openings and finally in communication with the second opening (24) of the pair of openings - at least one first manifold ( 36, 43), which is located between the cylinder block (9) and the level divider (17) and which, connected to one of these parts (cylinder block and 20 level divider) (25, 41) is provided with two at the interface (37-38); (44-45), one surface (38, 44) of which is located opposite the contact surface (18, 16) of the part (17, 9) to which the first distribution flange (36, 43) is connected (25, 41), and the second the surface (37, 45) is planarly perpendicular to the axis of rotation (7) and in contact with a planar surface (16, 18) attached to one of said two parts (9, 17) and also perpendicular to the axis of rotation, so that the so-called . passage openings (39-40); (42), of which 30 others (42) correspond to the cylinder openings (33) and are in constant communication with them so that one passage opening is in each case connected to one cylinder opening, and the others (39, 40) correspond to the first (39) and second (40) of the level divider (17). ) and are in permanent communication with each other so that each of the first (39) and second (40) through-openings i7 82295 is connected to one of the first (23) and second (24) openings of the level divider (17), respectively, and all through-openings open between two concentric circles. , the center of which is on the axis of rotation, characterized in that the passage openings (33, 42) associated with the cylinder block 5 are complementary to the first (23, 39) and second (24, 40) passage openings associated with the divider (17) and the passage opening associated with the cylinder block is substantially equal to the area between one of the two circles (34, 35) mentioned here and, on the other hand, the l between the first and second passage openings of the pair of passage openings so that the passage opening associated with the cylinder block can be sequentially communicated with the first passage opening associated with the level divider within the operating clearance. A mechanism according to claim 2, characterized in that the manifold flange (36, 43) consists of a thin body with passage openings (39, 40); (42) is formed in sections extending in similar cross-section from one contact surface of the manifold to another. 25 is 82295