Radial cylinder hydraulic machine with a distributor each cylinder

Abstract

A hydraulic machine includes radial cylinders including, oscillating radial cylinders arranged in a crown or star of cylinder-piston units, the pistons of the groups are made slidable on a crankshaft or with a cam, or on interposed members concentric to it, and realizing the reciprocating motion in the oscillating cylinders. The oscillating cylinders are placed in contact with a surface of distribution concentric or corresponding to the surface of oscillation of the respective cylinder on which a distributor body is placed separate from the machine body and housed in a seat in the body, or part fixed to the body, of the hydraulic machine, and each distributor body is mobile in its seat under the action of the pressure of liquid in connection on the back surface of the distributor body against the surface of distribution of the oscillating radial cylinder subject to the distribution.

Claims

1. A hydraulic machine comprising: a machine body including a plurality of cylinder-piston units including: oscillating radial cylinders; and pistons which are slidable on a crankshaft or with a cam, or on interposed members concentric to the crankshaft, and realize a reciprocating motion in the oscillating radial cylinders; and a single distributor body formed, on each cylinder, in a surface of distribution concentric or corresponding to a surface of oscillation of the respective cylinder, wherein said oscillating radial cylinders are put in contact with the surface of distribution on which each corresponding distributor body is placed, separate from the machine body and housed in a seat in the machine body, or part fixed to the machine body, of the hydraulic machine, wherein each distributor body is mobile in its seat under the action of a liquid pressure acting on a back surface of said distributor body to be pressed against the surface of distribution of the oscillating radial cylinder subject to the distribution of the corresponding distributor body, and wherein each distributor body comprises: a plurality of shaped ducts formed in the back surface of the distributor body; and a plurality of ports of distribution forming a passage for the liquid from the shaped ducts to a slit in the respective cylinder.

2. The hydraulic machine according to claim 1, wherein the back surface, with respect to said surface of distribution, of each distributor body is divided into liquid tight zones, each zone having an equivalent surface area, in order not to influence tightness according to a direction of a motion of the liquid.

3. The hydraulic machine according to claim 2, wherein said liquid tight zones, of the back surface of each distributor body, are made concentric and subdivided into a central zone and a peripheral zone.

4. The hydraulic machine according to claim 1, wherein the slit comprises a pair of slits, and each cylinder includes the pair of slits for the connection of a branch of the hydraulic circuit to one or the other corresponding pair of distribution ports for the connection of a branch of the hydraulic circuit, each pair of slits being made interposed and with an angular position relative to the axis of the cylinder corresponding to the maximum oscillation in the operation of the oscillating radial cylinder allowed to the machine.

5. The hydraulic machine according to claim 2, wherein a shaped duct of the plurality of shaped ducts is formed between the respective liquid tight zone and each port of the plurality of ports and comprises a hole with a predetermined cross-section.

6. The hydraulic machine according to claim 1, wherein each cylinder is hydraulically connected by means of a respective distributor body to annular channels for feeding the liquid from one channel, and discharging the liquid to another channel.

7. The hydraulic machine according to claim 1, wherein each cylinder is hydraulically connected by means of a respective distributor body to internal channels of feeding and discharge of the liquid from a static central body.

8. The hydraulic machine according to claim 1, wherein the ports of feeding or discharge in each distributor body have a protuberance of advance or delay in the opening or closing of the passage of the liquid of the distribution.

9. The hydraulic machine according to claim 1, wherein the ports are shaped with an edge facing the slit in the cylinder that has a swell whereby sections of passage of the liquid are variable with the variation of the angle of oscillation, in the hydraulic machine operated with reduced displacement.

10. The hydraulic machine according to claim 1, wherein the oscillating radial cylinders include a trunnion, and the hydraulic machine has a connection channel in the trunnion.

11. A hydraulic machine comprising: a machine body; a plurality of cylinder-piston units formed in the machine body, and including a plurality of radial cylinders and a plurality of pistons which are slidable on a crankshaft to realize a reciprocating motion in the radial cylinders; a plurality of distributors formed on the plurality of radial cylinders respectively, a distributor of the plurality of distributors being formed in a surface of distribution corresponding to a surface of oscillation of the respective radial cylinder of the plurality of radial cylinders, wherein a radial cylinder of the plurality of radial cylinders is in contact with the surface of distribution on which the distributor is placed, separate from the machine body and housed in a seat in the machine body, wherein each distributor of the plurality of distributors is mobile in the seat under the action of a liquid pressure acting on a back surface of the distributor against the surface of distribution of the corresponding radial cylinder, and wherein the distributor comprises: a plurality of shaped ducts formed in the back surface of the distributor; and a plurality of ports of distribution forming a passage for the liquid from the shaped ducts to a slit in the respective radial cylinder.

12. The hydraulic machine according to claim 11, wherein the back surface of the distributor is divided into a plurality of liquid tight zones each having an equivalent surface area, in order not to influence tightness according to a direction of motion of the liquid.

13. The hydraulic machine according to claim 12, wherein a shaped duct of the plurality shaped ducts is formed between the respective liquid tight zone and a corresponding port an comprises a hole with a predetermined section.

14. The hydraulic machine according to claim 11, wherein each radial cylinder of the plurality of radial cylinders is hydraulically connected by means of the respective distributor body to annular channels, for feeding the liquid from one channel, and discharging the liquid to another channel.

Description

SHORT DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a schematic section on a plane transverse to the axis of the motor shaft of a hydraulic machine with radial cylinders, here a hydraulic motor, in correspondence of the plane containing the cylinders of the star, according to the invention, provided with single distributors of the hydraulic fluid one for each cylinder at their external end of oscillation;

(2) FIG. 2 shows a schematic section II-II of the hydraulic motor with radial cylinders of FIG. 1 made on a cylinder at the upper dead centre;

(3) FIG. 3 shows a schematic section of a single distributor body present in the oscillation head of each cylinder of the hydraulic motor of FIGS. 1 and 2;

(4) FIG. 4 shows a schematic view axial to the axis of the cylinder and from the side of the feeding and discharge channels of the hydraulic fluid, of the single hydraulic distributor of FIG. 3;

(5) FIG. 5 shows a partially sectioned schematic view, in the surface of oscillation, of an oscillating cylinder of the hydraulic motor with radial cylinders of FIGS. 1 and 2;

(6) FIG. 6 shows a schematic view of a hydraulic machine with radial cylinders, here a hydraulic motor with a double crown of radial cylinders, wherein the cam is external and the central pin acts as a support and body with the channels of feeding/discharge of the hydraulic fluid: it is used in the power-operated wheel centres because it has the external skirt rotating with the cams to constitute a hollow motor shaft;

(7) FIG. 7 shows a schematic section on a plane transverse to the axis of the motor shaft of a hydraulic machine with radial cylinders, here the hydraulic motor of FIG. 6, in correspondence of the plane containing the cylinders of a star, according to the invention, equipped with single distributors of the hydraulic fluid, one for each cylinder at their oscillating internal ends;

(8) FIG. 8 shows a schematic section on a diametral plane containing the axis of the motor shaft of a hydraulic machine with oscillating radial cylinders on trunnions, here a hydraulic motor, in correspondence of the plane containing a cylinder and its axis of oscillation, according to the invention, and equipped with single distributors of the hydraulic fluid, one for each cylinder, on one of the two trunnions;

(9) FIG. 9 shows a schematic perspective view of an oscillating hydraulic cylinder, similar to that of FIG. 1, 2 or 5 in which the connection slit of the hydraulic cylinder with the ports has a spilt arrangement to increase the section of passage;

(10) FIG. 10 shows a schematic perspective view of a distributor for oscillating hydraulic cylinder, similar to that of FIG. 1, 3 or 4 in which the delivery/discharge ports of the distributor have a split arrangement to increase the section of passage towards the connection slits of the hydraulic cylinder of FIG. 9;

(11) FIG. 11 shows a schematic perspective view of an oscillating hydraulic cylinder, similar to that of FIG. 1, 2 or 5, and wherein the connection slit of the hydraulic cylinder with the ports has a split arrangement to increase the section of passage, as well as the oscillation of this cylinder is provided on the sealing surface of the hydraulic distributor;

(12) FIG. 12 shows a schematic view of a distributor like that of FIG. 10 from the side of the surface of oscillation of the cylinder;

(13) FIG. 13 shows a schematic diametral section XIII-XIII of the distributor of FIG. 12;

(14) FIG. 14 shows a schematic diametral section XIV-XIV of the distributor of FIG. 12;

(15) FIG. 15 shows a schematic view from the side of the channels of feeding/discharge of the distributor of FIG. 11;

(16) FIGS. 16a to 16h schematically show the movement of oscillation of the pair of slits on the cylinder with respect to the pair of ports of the distributor of FIGS. 12 to 15, during the cycle of a complete oscillation of the cylinder in sequence from 16a to 16h;

(17) FIGS. 17a, 17b and 17c show a schematic representation of the shapes of the ports with respect to a generic central slit of an oscillating cylinder, with no overlap, FIG. 17a, negative overlap, FIG. 17b, or positive overlap, FIG. 17c, respectively;

(18) FIGS. 18a to 18d schematically show a shape of the ports with respect to the generic central slit of an oscillating cylinder, according to the invention, with no overlap, in the position at the dead centres, and in three different phases of opening with a low angle of inclination of the respective cylinder in the oscillation, evidencing the progressiveness of the port of the section of passage between the involved port and the slit.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(19) In FIGS. 1 and 2, in a first embodiment of a single distributor for oscillating cylinder, according to the invention, one can see a hydraulic machine 1, here is represented a hydraulic motor with radial cylinders 2 arranged in a star pattern, placed to slide on a motor shaft 3, with a cam to constitute the crank 4, by means of known shoes 5 of the single piston. On the head of each cylinder there is a slit 6 of communication with annular channels 7 and 8, to the star of cylinders, to carry out the delivery and the return of the hydraulic fluid for operation. Each annular channel is provided, towards each cylinder, with a fluid feed radial duct 9. The two radial ducts 9 connected to a respective cylinder 2 feed the fluid in a seat 10 for housing a distributor body 11, housed with play, but sealed in said seat: each radial duct 9 is connected to a different zone of the surface of the distributor body, but on the same side, the zones are provided with a separation seal between them and towards the inside of the hydraulic machine. The distributor body 11 has on its inside shaped ducts 12 and 13, respectively, to put in hydraulic connection the different zones 14 and 15, respectively, of said distributor body with the oscillating cylinder 2 on the cylindrical surface of distribution 16, where there is the passage of the hydraulic fluid from the distributor body, through ports of distribution 17 and 18 corresponding to said shaped ducts 12 and 13, to realize the alternate passage in delivery and in discharge of the hydraulic fluid through said slit 6 at each of the two annular channels and the respective cylinder 2 as required by the instantaneous phase of the cycle.

(20) Furthermore, the cylinder 2 has trunnions 19 for defining an axis of oscillation with respect to which the cylindrical surface of distribution 16 is centred, that is to say, the oscillation occurs by means of the guide of the rotation surfaces 20 of the trunnions, which are connected in a rotating manner to the walls 21 and 22 of the hydraulic machine 1; each of the annular channels 7 and 8 is connected with a respective attachment 23 and 24 of the duct of the hydraulic circuit, on said walls of the hydraulic machine, by means of holes 25 in said walls. Therefore, the piston 26 is provided with a crown 27 which at the upper dead centre occupies the high part 28 of the cylinder 2 considerably reducing the harmful volume that remains occupied by the fluid. Moreover, in FIG. 3 one can see the seat 29 of the front seal, for the zone 14 of the shaped channel 12, as well as the seat 30, for the circumferential seal of the zone 15 of the shaped channel 13.

(21) The sizing of the zones 14, of the shaped channel 12, and zone 15, of the shaped channel 13, are calculated in such a way as to have the same surface and, therefore, the thrusts generated through them by the pressure of the hydraulic fluid are almost identical in proportion to the pressure. The pressure, which is present in the cylindrical surface of distribution 16, is balanced by the constancy of the pressure due to the equality of the surfaces of the zones 14 and 15, in such a way as to ensure a balance of the thrusts on the body distributor 11 and limit the thrusts between the trunnions 19 and the rotation surfaces 20 of the latter. The constancy of the thrust between the distributor 11 and cylinder 2 ensures the sealing on the surface of distribution also in the absence of specific holding means, because the mobility of the distributor body does not transfer all the thrust of the hydraulic liquid on the cylinder in the surface of oscillation of the trunnions, but only the residual thrust not compensated for between the thrust of the hydraulic liquid in the cylinder and the thrust on the surface of distribution.

(22) In FIGS. 6 and 7 one can see a further embodiment of hydraulic machine 31 with radial cylinders 32 arranged in a star pattern and having each piston 33 sliding on the internal cam 34; the cylinders are subdivided, in the representation of the hydraulic machine, here a hydraulic motor, on a double crown of cylinders and in which the internal cams 34 are connected and rotating with a hollow motor shaft 35, which is usually known to constitute a wheel centre with hydraulic motor, housed directly inside the driving wheels of a vehicle. The hydraulic machine 31 has a side wall 36, of connection to the supporting structure, not shown here, and a side wall 37 of attachment of an off-axis duct 38 and an axial duct 39, for the feeding and discharge hydraulic fluid to it; said ducts are extended in a static central body 40 of the hydraulic machine 31.

(23) As it can be seen in the Figures, each cylinder 32 is supported in its oscillation by means of trunnions 41 on the rotation surface 42, in a way similar to the cylinders 2; there being two crowns of cylinders arranged in a star pattern, between them is provided an intermediate support ring 43 of the rotation surfaces 42 of the trunnions 41 between the two crowns 44 and 45 of oscillating cylinders. Each cylinder 32 is constituted in a way similar to the cylinder 2 with a slit 6 in contact with a surface of distribution 16 of a distributor body 11. Each piston 33 has a shoe 5 sliding on said cam 24 of the crown 44, 45 of the cylinders arranged in a star pattern. Moreover, the piston 33 has a crown 27 which at the upper dead centre occupies a high part 28 of the cylinder 32, to reduce the harmful volume of hydraulic fluid that at every cycle remains inside the cylinder. Thus, as visible, each duct 38 or 39 in the static central body 40 is connected to a seat 46 of the distributor body 11 by means of connection channels, respectively, 47, from the axial duct 39, and 48 from the off-axis duct 38; the latter in correspondence of each crown of cylinders has an annular duct 49 to allow for the connection of the corresponding channels 48 of each cylinder, avoiding the central part of the static central body 40, that is to say, where there is the axial duct 39.

(24) In FIG. 8 one can see a further embodiment in which a usual hydraulic machine 50 with radial cylinders, here advantageously in the form of a motor, with the cylinders 51 oscillating on axes of oscillation defined by trunnions lateral to the oscillating cylinder, a supporting trunnion 52 and a trunnion of feeding 53 and discharge of the hydraulic fluid, which occurs by means of a channel 54 in the trunnion. In the rotation surface 55 of the trunnion of feeding 53 there is a distributor body 56, similar to the body 11 described at the head of the cylinders 2 or 32, here to connect for the distribution adjacent annular channels 57 and 58, internal to said rotation surface 55, for the delivery and discharge, which acts simultaneously as a surface of distribution of the hydraulic fluid. The annular channels 57 and 58 are connected by ducts in the axial direction 59 and 60, respectively, to the attachments 61 and 62 of feeding and discharge from the hydraulic circuit in which the hydraulic machine 50 is connected. In this way the side cover 63 of the motor case 64 allows for the passage of a second end 65 of the motor shaft 66 wherein, in the known embodiments, a rotating disc distributor is generally housed for the delivery/discharge of the hydraulic fluid from the cylinders. Finally, a usual piston 67 is placed in sliding contact on the crank 68 of the motor shaft in a known way. For similarity of construction the distributor body 56 is constituted and operates in a way similar to the already described distributor body 11. The distribution therefore occurs by the oscillation of a slit 69 present in the rotation surface of the trunnion of feeding 53 in correspondence of ports, in the distributor body towards the annular channels through the surface of distribution, ports connected to said annular channels 57 and 58, as described for the previous embodiments.

(25) In FIGS. 9 and 11 one can see embodiments of an oscillating cylinder 70 with rotation trunnions 71 and an oscillating cylinder 72 where the rotation surface 73 coincides with the surface of distribution and the function of positioning to rotation is performed by parts 74 of the surface of oscillation undercut with respect to the radial direction of positioning of the cylinder in the star of cylinders of the hydraulic machine in which they are inserted. In FIG. 10 one can see a distributor body 75, similar to the distributor bodies 2 and 32, with a different arrangement of the ports and of the shaped channels of distribution from and towards the oscillating cylinder. That is to say, the oscillating cylinders 70 and 72 have a double connection slit 76 through the surfaces of distribution with an increased section of passage with respect to the previous ports 6 or 69 because it is determined not by the width of the slits, but by the holes 77 present in them, which connect the surface of distribution 73 to the inside of the oscillating cylinder 70 or 72.

(26) Each of the two slits 76 is positioned at a radial angle, with respect to the axial direction D of the centreline of the relative oscillating cylinder 70 or 72 at an angle greater than the corresponding maximum angle of oscillation of said cylinder. In this way each single slit 76 behaves like a slit 6 or 69 of a distributor body 11 or 56 with the relative oscillation of the surface of distribution 73 of the cylinder on the surface of distribution 78 of the distributor body 75 with split ports 79, for a connection of the hydraulic fluid from a central zone 80, of connection of the shaped channels, and 81, for the connection of the hydraulic fluid from a peripheral zone 82, on the corresponding and opposite branch of the hydraulic circuit in the operation of the hydraulic fluid in delivery or discharge. The connection between the peripheral zone 82 and the ports 81 occurs by means of peripheral holes 83 between said zone and the ports; thus, the connection between the central zone 80 and the ports 79 occurs by means of central holes 84; thus the peripheral zone is delimited on the external diameter of the distributor body 75 by means of a seal housed in a circumferential hollow 85.

(27) In FIGS. 12 to 15 the shape is clearly shown with the already indicated numerical references; moreover, 86 indicates an annular channel in the peripheral zone 82 for distributing hydraulic fluid to the peripheral holes 83 in a uniform way; 87 indicates a front annular seat for a seal of delimitation between said peripheral zone 82 and said central zone 80.

(28) FIGS. 16a to 16h show the reciprocal oscillating movement between a distributor body 75, housed in its seat 88, of a generic motor case of a hydraulic machine with radial cylinders, on which a central duct 89, of feeding of the central zone 80, and peripheral ducts 90, of feeding of the peripheral zone 82 converge. In the sequence of the phases one can clearly see the following positioning of the slits 76 on the surface of distribution of the oscillating cylinder, in contact with the corresponding surface of distribution 78 in the distributor body 75. In FIG. 16a, with the cylinder and the piston at the upper dead centre, the slits 76 are in the closing position with respect both to the ports 81 of the peripheral zone and to the ports 79 of the central zone of the distributor body; then, in the following, FIG. 16b, the oscillation in the direction A of the cylinder begins the opening of the passage of hydraulic fluid from the ports 81 of the peripheral zone in the slits 76; in FIG. 16c the amplitude of the oscillation towards A is maximum, so FIG. 16d shows the return oscillation motion in the direction B of the cylinder, until reaching, at the lower dead centre, FIG. 16e, the closing position of the ports, both of the peripheral zone 81 and of the central zone 79, with respect to the slits 76. So again in the oscillation in the opposite direction, in FIG. 16f one sees that the slits 76, in the oscillation of the cylinder in the direction B, are put in communication with the ports of the central zone 79, until reaching the complete opening, in FIG. 16g; and, moreover, the completion of the cyclical oscillation motion can be seen in FIG. 16h in which, with a following oscillation in the direction A from the position of complete opening, of the ports of the central zone 79 towards the slits 76, the oscillation motion of the cylinder causes the closure of the passage of hydraulic fluid from the ports 79 of the central zone of the distributor body 75 towards the cylinder through the slits 76. At the end of the cycle of oscillation the position of the slits and of the ports in the distributor body 75 returns that of FIG. 16a, that is to say, again with the cylinder and the stroke of the piston in it at the upper dead centre.

(29) FIGS. 17a, 17b and 17c show the embodiments of a single slit like 6 or 69 of the arrangements with a distributor body 11 for single slit in the corresponding oscillating cylinder 2 or 32 or even in the trunnion of feeding 53. In fact, the ports 17 and 18 are made with no detachment or overlap with respect to the width of the slit 6, as shown in FIG. 16, in such a way as to realize no overlap, that is to say, a clear opening/closing of the passage of hydraulic fluid and with no possibility also of partial mixing of the flows of hydraulic fluid. In the case, on the other hand, of realizing a gentler or softer way of opening and closing of the hydraulic flow of fluid through the ports of delivery and discharge, there is provided a small protuberance of advance 91 towards the slit 6 of a port 92, for example the left one in FIG. 17b, so that, in the opening of the passage of fluid at the dead centres of the piston of the cycle of oscillation of the cylinder, the fluid begins to flow also a moment before the effective opening of the port; in a similar way the port 93 of the branch of the opposite hydraulic circuit has a small protuberance of delay 94 towards the slit 6, which maintains slightly in communication the port 93 with the slit 6 also in the position of centred overlap shown in FIG. 17b. This arrangement of the protuberances that anticipate and delay the passage of hydraulic fluid between the ports 92 and 93 and the slit 6 makes a negative overlap, that is to say, allows for a short mixture of the flows of hydraulic fluid inflowing/outflowing from the oscillating cylinder decreasing their noise and vibrations and realizing a gentle and soft operation of the hydraulic machine on which they are made. In particular embodiments, then, if precision and safety of the operation of distribution are required, the overlap can be made greater than the simple port of the slit 6, as shown in FIG. 17c, in it in the position of passage at the so-called dead centres of the oscillation of the cylinder between the slit 6 and the ports 17 and 18 of delivery/discharge of the distributor body there remains, due to construction, a thin overlap strip 95 in which the oscillation between the ports and the slit occurs, but not the passage of the hydraulic fluid between them, to make a positive overlap of distribution.

(30) As visible, finally, in FIGS. 18a to 18d that show successive moments of port of the passage from a shaped port 96 of the hydraulic fluid, the constitution of the ports of delivery/discharge of the hydraulic fluid from the oscillating cylinder can occur also with a variable section of passage of the port with the increase/decrease of the amplitude of oscillation of the cylinder. This particular construction is useful in hydraulic motors with oscillating radial pistons and variable displacement, that is to say, which from a maximum value can be reduced to a minimum value, without for this reason cancelling the displacement, that is to say, the amplitude of oscillation; the motor, not having displacement would behave like a closedthat is to saylocking valve, failing its function of transforming the motion of the hydraulic fluid into rotational motion of the motor shaft. Said specific Figures show a variable port 97 to the left of the slit 6 and in a position of no overlap, as said for FIG. 17a; here, however, the variable port 97 has a swell 98 facing the slit 6 to open a minimum passage 99 of hydraulic fluid with a small angle of oscillation, FIG. 18b. As oscillation increases, the swell 98 opens the passage of hydraulic fluid in a more consistent way, as can be seen in FIG. 18c, of an increased passage 100, and 18d, of a complete passage 101, in which the hydraulic fluid finds the port 97 almost completely open on the edge of the slit 6 facing it.

(31) The operation of the radial hydraulic machine described above, provided with oscillating cylinders 2, 32, 70 or 72 with one single distributor for each cylinder, occurs by the oscillation of the cylinder that, as known in the art, opens and closes the respective ports of feeding or discharge of the hydraulic liquid. Moreover, the present invention introduces a new solution in the way of realizing and operating the position of the ports of feeding and discharge and such as to significantly modify the way of construction of the hydraulic machines with oscillating radial cylinders in which it is applied.

(32) In fact, as it has been seen in the prior art, the main disadvantage was the sealing security of the ports on the surface of oscillation, which is also the surface of distribution of the hydraulic liquid from the body of the machine to the oscillating cylinder, for the correct operation. Mainly the pressure of the hydraulic liquid in one of said ports is generally different from the pressure in the other. In the solution proposed by the present invention this pressure, besides being present in the port, is also present in a back surface of the distributor body 11, 56 or 75, that is to say, in the sealing zones 14 or 15 or in the central zone 80 and peripheral zone 82, with respect to the cylinder head, in such a way as to push said body against the surface of oscillation of the cylinder. Moreover, the ports are always at least two, so considering the port with greater pressure, the other is obviously connected to the branch of the hydraulic circuit in discharge, it is the same pressure that acts inside the cylinder 2, 32 or 75. In order to realize the most convenient operation of the distributor body 11, 56 or 75 described above, the force exerted by said pressure acts on the back face of the distributor body itself and ensures its contact, on the surface of distribution 16, 55 or 78, in all operating conditions of the hydraulic machine and, moreover, the residual thrust from the compensation of the axial force developed in the oscillating cylinder by the pressure of the liquid that opposes it is the only one that is released through the surfaces of oscillation 20, 42 or 55 of the trunnions 19, 41 or 53 of the cylinder; that is to say, the thrust on the trunnions is reduced to values limited to the guide of the cylinder in the oscillation, but is not subject to the strong thrusts that are generated in the hydraulic machine with the oscillating cylinders provided with trunnions known in the art. Thus, considering that the high pressure can indifferently be present in one or the other of the ports of feeding or discharge, the back surface of the described distributor body is divided into two areas having an equivalent surface. In this way it is indifferent which of the two branches is under pressure and which in discharge: in any case the pressure that acts on the distributor body 11, 56 or 75 realizes the greatest thrust towards the surface of distribution in order to ensure tightness in the passage of the hydraulic liquid from the ports to the slit in the oscillating cylinder.

(33) Said operation does not comprise completely the embodiment of FIG. 8 because the trunnions in it make up the support to the oscillation in the known way and also the surface of distribution, but said realization allows to free the encumbrance caused by the known disc distributor, arranged axially to the motor shaft, therefore to be able to realize hydraulic machines with a double connection of the motor shaft on both sides as visible in the Figure. Moreover, said construction shown is specifically a hydraulic motor with oscillating radial cylinders and, with the present invention, the change in the position of the distributor, from the usual of the disc type in a position axial to the shaft in the new represented shape, can also be made on hydraulic machines, or better hydraulic motors, already built, that is to say, it can be applied in a second moment with respect to the construction, or, can be made making only partial changes without designing a new hydraulic motor with oscillating radial cylinders with trunnions.

(34) The operation, instead, of the embodiment of the distributor body of FIG. 9 and FIGS. 12 to 15 is explained by the sequence of the phases of operation, that is to say, of oscillation of the cylinder of FIGS. 16a-16h, in which one sees that fundamentally the behaviour of the distributor body 75 operates in the way described above for the previous embodiment. The difference consists of the shape of the two slits 76 shown in the surface of distribution 73 of the cylinder; each slit is connected inside the cylinder through holes 77, which determine the section of passage of the hydraulic liquid, in such a way as to obtain a wide section of passage of hydraulic liquid, wider than that obtainable from the single slit 6 of the cylinders 2 or 32. Correspondingly the surface of oscillation 78 of the distributor body 75 has pairs of ports 79 and 81 angularly placed to simultaneously perform the closing of the ports at the dead centres of the stroke of the piston in the cylinder and the port of one or the other pair of ports, when opposite said pair of slits, during oscillation. Each port is connected to the back surface of the distributor body 75 with central holes 84, to connect the ports 79 to the central zone 80, and with peripheral holes 83, to connect the peripheral zone 82. The development of the two surfaces of the central and peripheral zone are similar and slightly greater than the area developed by the bore of the cylinder involved at the distributor body. The sections of passage from said zones on the back surface of the distributor body and the pairs of ports 81 and 79 are defined by said peripheral 83 or central holes 84.

(35) Finally, the distribution ports 17, 18 or 79, 81 can, in order to realize gentler and less loud operations in the opening and closing of the passage of hydraulic liquid between them and the corresponding slit in the cylinder, be provided with contact edges with negative overlap, even if it is made only at one point of the side of the port, as visible in FIG. 17b in which the ports 92 and 93 re provided with protuberances 91, of advance, and 94 of delay, respectively, in such a way as to realize even a very short passage of liquid from one port to the other, thus limiting the drops of pressure of the liquid in the cylinder. In a similar way, if a secure closure of the ports is required, it is possible to realize a positive overlap with an overlap strip 95 between the ports and the edges of the slit 6.

(36) With the specific shape of the edge of the ports, as shown in FIGS. 18a to 18d, the edge itself can be made not linear in such a way as to make progressive, with the respective angular position reached, the section of port of the passage of a port with respect to the slit in the cylinder, where a so shaped distributor body act. In fact, in FIG. 18a the two shaped ports 96, drawn close to the slit 6, realize a variable port 97 because they are of a shape with a swell 98 of the edge of the port drawn close to the slit 6. In this way the passage of the relative position of the slit 6 towards a shaped port 96 generates an increasingly wide section of passage as, in the motion of oscillation of the cylinder, the slit 6 moves towards the shaped port 96 enlarging on the section of passage, but not in a sudden way: from the minimum passage 99 to the increased passage 100 to the complete passage 101 in which the front of the opening is almost completely open because of the variability of the side of the port due to the swell 98. In this way in the operation of hydraulic machines with reduced displacement, typical of the hydraulic motors operated with minimum displacement, the section of passage of the hydraulic fluid allows to keep the speed of the hydraulic liquid in the passage of the port constant.

(37) The advantages in the realization and use of a hydraulic machine, with oscillating radial cylinders provided with a distributor for each single cylinder as described above, are expressed by a simple construction, for the realization of the distributor that, being made very close to the cylinder, does not need long connection channels of the single cylinder with the distributor, reducing the volume of hydraulic liquid between the cylinder and the surface of distribution, with respect to the distribution realized with the rotating discs known in the art.

(38) Moreover, the distribution of the hydraulic liquid by the described distributor body 11, 56 or 75 allows to balance in a correct way the sealing of the liquid in the surface of distribution 16, 55 or 78 both for the thrusts transmitted on it and for the reduction of the thrusts on the trunnions 19, 41 or supporting surface 20, 42 or 73 and 74, and guide in the rotation of oscillation of the cylinder involved. That is to say, the possibility of movement allowed to the distributor body 11, 56 or 75 allows to realize the distribution of the hydraulic liquid as precisely as possible with respect to the known art.

(39) The realization of the single distributor for each cylinder, as visible in the Figures, allows to make hydraulic machines, in particular hydraulic motors, that, besides reducing axial sizes and encumbrances, allow for the construction of motor shafts 3 or 35 with two free ends 65 and 66 and this is also possible on already built hydraulic machines or hydraulic motors.

(40) Moreover, the realization of double slits 79 and 81 rather than one single slit in the cylinder 70 or 72 allows to increase the section of passage of the hydraulic liquid in the surface of distribution 73, so the distributor body 75 is more balanced as the zones of pressure on its back surface are concentric to a central zone 80 for two ports 79 and a peripheral zone 82 for the other two ports 81.

(41) Furthermore, the described shape of the distribution ports allows to adapt the mode of operation of the hydraulic machine to the specific needs also of hydraulic motors with variable displacement in such a way as to considerably improve operation with minimum displacement.

(42) In conclusion, the most evident advantages are achieved with one single distributor body for each cylinder that is made mobile and balanced in the thrusts to which it is subject, but further and more significant advantages are obtained with the shape of the edge of the ports, as described above.

(43) Obviously, an expert of the sector, in order to meet specific needs, may bring several changes to the above-described hydraulic machine with oscillating radial cylinders and single distribution members for each cylinder, all included within the scope of protection of the present invention as defined by the following claims. Thus, even if less conveniently, thanks to the subdivision of the back surface of a distributor body into central zone and peripheral zone each zone can be connected to a respective single port in correspondence of and operating with on single slit in the head of the cylinder involved.

(44) Moreover, even if less conveniently for production costs, the surface of distribution in addition to the cylindrical shape shown can also be of a convex, barrel-like or even spherical shape, so in combination with the sizing of the zones of pressure of the back surface of the distributor body the contact and the liquid tightness of the distributor is improved.

(45) Furthermore, the distributor body can be made with one single port and associated with a surface of distribution of a trunnion provided with a connection channel with the cylinder, similarly to what is shown in FIG. 8, but with both trunnions provided with a channel, with a respective slit centred in the position corresponding to the dead centres of the oscillating piston-cylinder complex, which connect the cylinder with annular ducts one on each side of the crown of cylinders. The distributor body for a similar realization has only one port angularly placed on the surface of rotation and distribution in such a way as to realize one of the overlap positions described in FIG. 17a-c or 18a-d and on the other distributor body with single port the corresponding port to realize the described positioning between the ports and the slit.

(46) Moreover, an internal cam, like the cam 34 of the hydraulic machine of FIG. 6 or 7, can be made with several protuberances to realize several cycles of a single cylinder in the single rotation of the hollow motor shaft 35. Finally, said internal cams in the case of a multiple crown of cylinders can be angularly offset in such a way as to increase the number of the thrust pulses and generate in a hydraulic motor a uniform torque.