The present invention relates to fluidic machines, and more particularly it concerns an internal gear fluidic machine, in particular a pump, with variable capacity.
Preferably, but not exclusively, the present invention is applied in a pump for the lubrication oil of a motor vehicle engine.
In several technical applications, for example in order to have lubrication oil circulate under pressure in motor vehicle engines, positive displacement internal gear pumps are often used. These pumps generally comprise: a fixed body; an external orbital to gear rotating in said body about a first rotational axis and having an internal toothing; an internal orbital gear rotating inside the external orbital gear about a second axis, different from the first one, and having an external toothing meshing with the internal toothing of the external orbital gear with only partial hydraulic seal; a transmission member, generally driven by the vehicle engine, in order to impart the rotation to one of the two orbital gears, which in turn brings the other into rotation due to the meshing of the respective toothings. The toothings, which have a different number of teeth, define a succession of variable volume chambers among them, and oil is conveyed from an intake port to a discharge port through said chambers.
In such pumps the capacity, and hence the oil flow rate at the outlet, depends on the rotation speed of the engine, and therefore the pumps are designed so as to provide a sufficient flow rate at low speed, in order to ensure lubrication also in such conditions. If the pump has a fixed geometry, at high rotation speed the flow rate is higher than that required, resulting in an unnecessary energy consumption and, finally, in an increase in fuel consumption.
Similar problems are encountered in pneumatic pumps or when the above structure is used as a motor, either hydraulic or pneumatic.
In order to reduce the performance variability as the operating conditions change, and to obviate the above drawbacks, variable capacity fluidic machines have already been proposed, in which the variation of the flow rate is obtained by varying the axial extension of the engagement region between both orbital gears.
A first example is disclosed in JP 56020788. In such a solution, the capacity adjustment is obtained by translating the orbital gear driven by the motor: the coupling between the rotational movement of the pump and the translational movement for the capacity adjustment results in a high absorbed torque, which limits the advantages resulting from the capacity adjustment.
Another example is the pump disclosed in WO 2004/003345. In this pump, the rotational and translational movements are separated, in that the rotational movement is transmitted to one of the orbital gears and the capacity is varied by means of a translation of the other orbital gear, so that the problem of the high absorbed torque is solved. However, a problem with this prior art pump is that the capacity adjustment is based only on the control of the pressure in a space communicating with the delivery chamber. Under these conditions, also an overpressure occurring upstream of the main control channel of the engine would be considered as being due to a high rotation speed and would consequently lead to a reduction in the oil flow rate, with risks of damaging the engine because of an insufficient lubrication.
Moreover, in this prior art pump, the translation of the orbital gear is not obtained directly, but indirectly, thanks to a small piston which slides as the fluid pressure changes and causes the translation of the external orbital gear. This makes the pump structure more complex and its reaction slower.
Document GB 2 440 342 discloses a pump having a substantially star-shaped internal ring providing an axially directed feed. Such an internal ring has a plurality of drill ways connecting the pumping chambers with the inlet and outlet ports depending on the angular position of the internal ring. The device of said document has some drawbacks.
A first drawback is that the drill ways must have reduced transversal cross-sectional sizes in order to ensure the required structural strength of the internal ring. Yet, reducing the transversal cross-sectional sizes of the drill ways has the drawback of entailing cavitation problems at high rotation speeds of the pump.
A further drawback is that, in order to increase the pump displacement, it is necessary to correspondingly increase the axial sizes of the inlet and outlet ports, whereby the pump is made significantly bulky in axial direction. The great axial size can originate problems for mounting the pump, which generally is housed in the bottom part of the engine. For instance, if the axial size of the pump increases, the risk exists of interfering with the proper movement of the camshaft.
It is an object of the present invention to provide a hydraulic machine with gears, which obviates the drawbacks of the prior art.
According to the invention, this is obtained in that a translating mechanism, causing the sliding of the axially displaceable orbital gear, defines, besides the space in communication with the high pressure chamber of the machine, a second capacity adjustment space where second pressure conditions exist that are dependent on operating conditions of an element, different from the high pressure chamber, of a fluidic circuit in which the machine is connected, and the translating mechanism is axially slidable in the supporting part either in response also to the pressure conditions existing in the second capacity adjustment space, or in response to a combination of the pressure conditions existing in both adjustment spaces.
Advantageously, the axially slidable gear is made as an integral part of the translating mechanism.
In the preferred case of use of the machine as a pump for the lubrication oil of a motor vehicle engine, the first adjustment space is in communication with a delivery side of the pump. Moreover, in a first embodiment, the second adjustment space receives lubrication fluid under pressure sent back from the engine to the pump, and in a second embodiment, in which the capacity of the machine is established by an external management logic responsive to the operating conditions of the engine, when the pump is made to operate at its maximum capacity the second adjustment space is in communication with the oil sump in order to discharge to the latter oil leaks, if any, occurring in the pump, and when the pump is made to operate at a lower capacity than the maximum capacity such space is in communication with the delivery side of the pump.
In further advantageous manner, differently from what disclosed in GB 2 440 342, the pump according to the present invention allows implementing a radially directed feed, by means of openings defined by cuts that can be made with sizes adjustable depending on the manufacturing requirements. Consequently, it is possible to freely dimension the transverse cross-sectional sizes of the openings so as to avoid cavitation problems in the pump.
Another advantage of the pump according to the present invention is that the displacement can be increased by increasing the radial sizes of an external orbital gear, an internal orbital gear and a toothed portion of a star-shaped cap belonging to such a pump. Thus, the increase in the displacement does not negatively affect the axial size of the pump, differently from what occurs instead in GB 2 440 342.
The invention also concerns a method of varying the capacity of an internal gear fluidic machine. According to the method, a first capacity adjustment space communicating with a high pressure chamber of the machine is created, and the capacity of the machine is varied by making one of both gears of the machine axially slide relative to the other, in response to first pressure conditions existing in the first capacity adjustment space, in order to change the extension of an area over which the teeth of both gears mesh. The method further comprises: creating a second capacity adjustment space; establishing in the second space second pressure conditions that are dependent on operating conditions existing in an element, different from the high pressure chamber, of a fluidic circuit in which the machine is connected; and making the slidable gear axially slide either in response also to the pressure conditions existing in the second capacity adjustment space, or in response to a combination of the pressure conditions existing in both capacity adjustment spaces.
The invention will be described now in further detail with reference to the accompanying drawings, which show a preferred embodiment given by way of non-limiting example and relating to the use of the invention as a pump for the lubrication oil of a motor vehicle engine, and in which:
The following description, by way of example only and for the sake of clarity and simplicity of the description, will refer to a pump arranged with vertical axis and driven from the bottom, and the terms “upper”, “lower”, “top”, “bottom” and so on are therefore referred to such an orientation.
Referring to
Operating part 100 comprises, in conventional manner, a first gear 2 (external orbital gear) having an internal toothing, e.g. with five teeth 2A (
External orbital gear 2 is mounted so as to be axially slidable relative to internal orbital gear 4 in order to vary the pump capacity as the operating conditions vary, in particular in order to reduce such a capacity, and hence the flow rate of the oil, at high rotation speeds. As it will be described in greater detail below, the adjustment can be controlled either by the pressure actually existing in the engine, or by the pressure inside the pump (delivery pressure). This allows safeguarding the integrity of the whole lubrication system and avoiding flow rate reductions in case of pressure increases due to anomalous conditions and not to an actual increase in the rotation speed. Moreover, since one of the orbital gears is made to rotate by shaft 6 and the capacity is adjusted by means of a translation of the other orbital gear, the pump rotational movement is decoupled from the capacity adjustment, with a consequent reduction of the absorbed torque with respect to solutions in which the same orbital gear performs both movements.
External orbital gear 2 is rigidly connected for the rotational and translational movements to an external ring 8, mounted with interference on the bottom end of external orbital gear 2 so as to abut against a step 7 of the surface thereof. In correspondence with the coupling region of external orbital gear 2 and ring 8, the edges of such elements are provided with cuts 12 on external orbital gear 2 and cuts 10 on ring 8, respectively, defining openings 13 (
A first cap (lower cap) 14 is housed inside ring 8 and both the bottom base of external orbital gear 2 in conditions of maximum capacity of the pump, and the bottom base of internal orbital gear 4, abut against the top surface of the cap, as shown in
In its upper part, above internal orbital gear 4, cavity 25 of orbital gear 2 houses a second cap (star-shaped cap) 18 having a toothed lower portion 19, the external surface of which is shaped in complementary manner to the internal surface of external orbital gear 2, and a cylindrical upper portion 20. The latter is received in a cylindrical cavity of a third cap (upper cap) 22. Upper cap 22 is mounted with interference on the upper portion of external orbital gear 2 so as to be rigidly connected thereto for the rotation and the translation, and abuts against a step 9 (
Toothed portion 19 of star-shaped cap 18 is introduced in substantially sealed manner into cavity 25, for instance so that its bottom base is substantially in contact with the top base of internal orbital gear 4, and its top base defines, with the top of the cavity of upper cap 22, a chamber 24 (second adjustment space) communicating with a delivery chamber 48 (
Upper cap 22 is received in a cavity 60 (
Referring also to
The operation of the pump according to the invention will now be described, referring also to
In conventional manner, the torque transmitted by shaft 6 is applied to internal orbital gear 4 that, by rotating, makes the external orbital gear rotate, thereby allowing the pump to convey from intake chamber 46 to delivery chamber 48 oil sucked from the sump and compressed because of the passage through the different chambers 11. Oil under pressure arrives from the motor into chamber 15 between ring 8 and the bottom of cavity 40, as shown by arrow F1 in
At low rotation speeds of the engine (
The delivery pressure of the pump present in chamber 24 determines operating conditions similar to those described above. Under regular operating conditions, the pressure in chamber 24 is not sufficient to overcome the force exerted by spring 28 (arrow F5,
In both cases, while the orbital body is displacing, internal orbital gear 4 always meshes with external orbital gear 2, thereby ensuring the pump operation.
It is clear that the invention allows attaining the desired objects. Actually, the translational movement of the orbital body, and hence the possible reduction in the capacity of pump 1 and in the oil flow rate, is controlled by the oil pressure in two spaces 15 and 24, which are in communication with two different points of the lubrication circuit, namely the engine and the delivery side of the pump. Hence, on the one hand, through the pressure signal sent to the pump through duct 50, it is the engine itself that requires of the pump the oil flow rate actually necessary for the operating conditions existing at a given instant. On the other hand, a pressure increase occurring upstream the main control channel of the engine, for instance due to a filter obstruction or in case of a cold start, is converted into an overpressure in the delivery channel which, once the safety threshold is exceeded, brings the pump to hydraulic short-circuit or oil recirculation conditions, thereby avoiding damages to the engine because of an insufficient lubrication.
Moreover, the flow rate adjustment is obtained by directly acting on the slidable member, and not indirectly, by means of a piston which in turn pushes the slidable member: hence the structure is simpler and the response is faster.
In such a configuration, delivery duct 44 is connected to a port (port D) of a distribution valve 110, for instance a slide valve driven by a control unit 120, e.g. a solenoid valve, electrically operated so as to change its state depending on the operating conditions of the engine, detected by suitable sensors (not shown). In particular, solenoid valve 120 takes a first or a second state corresponding to the pump operation at the maximum capacity (and maximum flow rate) and to the capacity adjustment to a value below the maximum, respectively, and consequently it makes distribution valve 110 take a first and a second state.
In the first state of both valves, shown in
In the second state, shown in
It is to be appreciated that in both states an overpressure, if any, in pump delivery chamber 48 due to any operation irregularity will cause the displacement of external orbital gear 2, independently of the valve-conditions.
Also such a configuration maintains the safety characteristics related with a control of the capacity variation based on two different pressures.
It is clear that the above description has been given only by way of non limiting example and that changes and modifications are possible without departing from the scope of the invention.
For instance, even if the drawings show an orbital body comprising three separate elements 2, 12 and 22 rigidly connected together for rotation and translation for instance thanks to an interference mounting, the orbital body could be a single body suitably shaped so as to form external orbital gear 2 and to define both spaces 15 and 24 causing the translational movement of the orbital body.
Moreover, even if it has been assumed that internal orbital gear 4 is rotated by the shaft and external orbital gear 2 is slidable on the internal orbital gear in order to vary the pump capacity and forms the member distributing the fluid from intake chamber 46 to internal chambers 11 of the pump and from such chambers to delivery chamber 48, it is self-evident that the tasks of the two orbital gears could be mutually exchanged, even if the described solution is preferable for sake of constructional simplicity.
Further, even if the invention has been disclosed with reference to its application to a pump, the embodiment shown in
Advantageously, openings 13 defined by cuts 10 and 12 can be made with sizes that can be suited to the constructional preferences. Consequently, it is possible to freely dimension the cross-sectional sizes of openings 13 so as to avoid cavitation problems in the pump.
Another advantage is that the displacement can be increased by increasing the radial sizes of external orbital gear 2, internal orbital gear 4 and toothed portion 19 of star-shaped cap 18. Thus, the increase in the displacement does not negatively affect the axial size of the pump.
Of course, the pump or the motor could be pneumatic machines instead of hydraulic machines. Also, the individual elements described here can be replaced by functionally equivalent elements.
Number | Date | Country | Kind |
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TO2009A000290 | Apr 2009 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2010/051621 | 4/14/2010 | WO | 00 | 12/6/2011 |