FR2689185A1 - Engine oil pump assembly. - Google Patents

Abstract

The invention relates to an oil pump assembly. It relates to an assembly which comprises an oil pump which comprises a housing (1) having an inlet port (9) and two outlet ports (10, 11), and toothed inner and outer rotors (3, 4 ) which delimit between them a series of chambers (5) of variable volume which can be connected to the inlet and outlet ports (9, 10, 11). A controller connects the first and second output lumens (10, 11) when the pressure to the first output lumen is less than a predetermined value, and connects the second output lumen to the input lumen when the pressure at the first output light is greater than the predetermined value. Application to internal combustion engines.

Description

The present invention relates generally to oil pumps,

  and more specifically it relates to trochoidal type oil pumps which supply lubricating oil to various moving parts of an internal combustion engine or the like. More specifically, the invention relates to an assembly which comprises an oil pump and a device oil flow control. Usually, a trochoidal type oil pump includes a pump housing having inlet and outlet ports formed in opposite walls. A drive shaft which is driven by a crankshaft of the

  engine passes through the crankcase between the opposite walls.

  An internal rotor with external teeth connected concentrically

  to the drive shaft and an externally toothed outer rotor which eccentrically surrounds the inner rotor, maintaining eccentric cooperation of the rotor teeth

  internal and external, are arranged inside the housing.

  Thus, a series of chambers of variable volume is deli-

  moth between inner and outer rotors and communicate

  selectively with the entry and exit lights.

  When the inner and outer rotors rotate together due to rotation of the drive shaft,

  Chambers of variable volume are subject to change

  volume and therefore aspire to a lubricating oil.

  fiante the entrance light and chase it by the exit light Thus, an action called "pumping" is performed

by the pump.

  Since the drive shaft of the internal rotor is usually driven by the motor crankshaft, the pump discharge is almost proportional to the rotational speed of the motor. This arrangement tends to cause an excessive flow of the pump when the engine is running. high speed Thus, in practice, a relief valve is mounted downstream of the outlet lumen so that it regulates the amount of lubricating oil transmitted to the moving parts of the engine Thus, when the pressure of the oil in the light of The output increases and exceeds a predetermined value, the relief valve is controlled to open a discharge oil passage. However, this precaution allows the pressure in the chambers of variable volume to increase to this level. predetermined high and therefore causes a marked increase in the energy required to drive the pump This then causes a significant loss of energy ie the engine. One of the precautions enabling the aforementioned problem to be solved is described in the first publication of the Japanese patent application 63-1781. In this embodiment, an annular support member for the outer rotor and a member for adjusting the angular position of the Annular member is used The annular member has a circular opening in which the outer rotor is arranged to rotate and an outer cylindrical wall which is eccentric with respect to the circular opening The annular member is supported by the housing of the pump so that it can turn and that its wall

  cylindrical outer is concentric to the inner rotor.

  Thus, because of the work of the

  position, when the angular position of the annular

  has changed relative to the pump housing, the position of the series of variable volume chambers relative to the input and output lights is changed if

  although the flow pumped by the pump can be adjusted.

  However, even in this prior art oil pump, the use of the annular member and the position adjustment member leads to a complicated, cumbersome and very expensive construction of the pump. The invention therefore relates to the realization of an oil pumping installation which has a simple construction, a small size and a little manufacturing

expensive.

  The invention thus relates, in a first aspect, to an assembly having an oil pump which comprises an oil pump which has a housing having an inlet lumen and a first and a second outlet lumen, and inner and outer rotors. teeth arranged in the housing of the pump so that they delimit between them a series of variable volume chambers that can be connected to the input and output lights, the first output light being placed downstream of the second output light in the fluid flow direction in the oil pump, and a control device for connecting the

  first and second exit light when the

  to the first output light is less than a predetermined value, and to connect the second output light to the input light when the pressure at the first output light is greater than the value

predetermined.

  In a second aspect, the invention relates to an assembly having an oil pump that includes a pump housing having an inlet lumen and a first and a second outlet lumen, an inner rotor mounted so that it can rotate within the housing. housing, the inner rotor having outer teeth integrally formed thereon, an outer rotor mounted to rotate within the housing and eccentrically surrounding the inner rotor, the outer rotor having internal teeth thereon integral, the inner and outer rotors being engaged by their respective teeth so that they delimit between them a series of chambers of variable volume, the first output light being placed downstream of the second outlet lumen in the flow direction fluid in the oil pump, a first and a second exhaust passage from the first and second outlet respectively, a discharge passage having a first end tee is connected to the inlet lumen, and a switching valve which connects the second discharge passage to the first discharge passage while isolating the discharge passage when the pressure in the first discharge passage is less than one. predetermined value, and which connects the second exhaust passage to the discharge passage, while leaving the first exhaust passage, when the pressure in the first exhaust passage is greater than the predetermined value.

  Other features and advantages of the invention

  will be better understood by reading the description

  which will follow of embodiments, made with reference to the accompanying drawings in which: Figure 1 is a schematic view of an assembly having an oil pump in a first embodiment of the present invention; and FIG. 2 is a view similar to FIG. 1 but showing a second embodiment of the present

invention.

  Referring to FIG. 1, the drawings show

  An assembly having an oil pump in a first embodiment of the present invention. The assembly having the oil pump is intended to be used in a

internal combustion engine.

  In the figure, reference numeral 1 denotes a pump casing mounted on a front end of a cylinder block (not shown) of a motor. An open end of casing 1 of the pump is closed by a cover which is not closed. represented A drive shaft 2 goes into a

  central part generally of the casing 1 of the pump.

  The drive shaft 2 is driven by a crankshaft of the engine, although the drawing does not indicate it. The inner and outer rotors 3 and 4 are mounted so that they can rotate in a bore 1 of the housing 1. 3 is concentrically connected to the shaft 2 and has nine outer teeth 3a integrally formed thereon. The outer rotor 4 eccentrically surrounds the inner rotor 3 and has ten inner teeth 4a formed integrally therewith. external rotor 4 is shifted by

  relative to that of the internal rotor 3 by a determined distance

  As shown, the teeth 3a and 4a have inner and outer rotors 3 and 4 cooperate eccentrically and

  Thus, on the one hand, a series of chambers 5 of variable volume are defined. Thus, during the rotation of the inner and outer rotors 3 and 4, the chambers 5 undergo a change of volume one after the other.

  The pump housing 1 comprises, in the left part of the drawing, a curved chamber 6 for oil inlet and, in the right part, a first and a second chamber

7 and 8 oil outlet.

  As shown, these three chambers 6, 7 and 8 are

  exposed to chambers 5 of variable volume

  the oil inlet chamber 6 is exposed to the so-called "front" variable volume chambers which have just been created during operation of the pump, and the first oil outlet chamber 7 is exposed to

  5 "rear" rooms that are about to disappear.

  During the operation of the pump, however, the second oil outlet chamber 8 is exposed to specific chambers 5 which are about to undergo a reduction in volume, just after having taken their maximum volume. Thus, the first chamber 7 oil outlet is placed downstream of the second oil outlet chamber 8 in the direction of circulation of the oil in the pump. In addition, the exposed region of the first oil outlet chamber 7 is larger. than that of the second chamber 8

oil outlet.

  The oil inlet chamber 6 is connected to an oil inlet port 9 and the first and second oil outlet chambers 7 and 8 are connected to an oil inlet port

  first and second light 10 and output lh respectively

  As shown, the first and second oil outlet apertures 10 and 11 are separated by a partition structure 14 which has inclined walls 14a and 14b exposed at the level of the first and second openings.

  second light 10 and 11 of oil outlet respectively.

  The respective inclined walls 14a and 14b are separated

  by a distance slightly greater than the pitch of the adjoining teeth.

  4 of the outer rotor 4. The oil inlet port 9 is connected to an oil sump 12 of the engine through an oil inlet passage 13. Usually, an oil filter (not shown) is mounted on the passage 13 of oil inlet. The first and the second oil outlet lumens 10 and 11 are connected to a first and a second oil discharge passage 16 and respectively The first oil discharge passage 15 joins a main oil header 17 of the engine, and the second oil discharge passage 16 has a downstream end 16b which is connected to the first oil discharge passage 15 The second oil discharge passage 16 has a switching valve 19 to two positions connected thereto A discharge passage 18 has a first end 18b which is connected to the oil inlet passage 13 and another end 18a which is connected to the switching valve 19.

  The switching valve 19 is of a type with a pres-

  pilot pressure recalled by a spring Thus, the pressure of

  oil in a downstream part of the first pass 15 of

  The cupping penetrates through a pilot passage 20 into a pilot pressure chamber of the valve 19 so that the spool thereof is moved despite the restoring force of the spring. Thus, the switching action of the valve 19 is obtained. by a difference between the pilot pressure and the restoring force of the spring 19a When the pressure at the downstream portion of the first passage 15 is less than the predetermined level, the slide takes the represented position in which the upstream and downstream portions 16a and 16 b of the second passage 16 communicate and the discharge passage 18 is blocked. However, when the pressure of the downstream portion becomes greater than a predetermined level, the slide moves to another position, despite the force of the spring 19a, in which the upstream portion 16a of the second passage 16 communicates with the discharge passage 18 and the downstream portion

16 b is clogged.

  The reference 21 designates a pressure adjustment valve placed in a return passage 22 disposed between the downstream part of the first passage 15 and the oil inlet passage 13. By virtue of this pressure adjustment valve 21, the pressure oil transmitted to the engine can

  be adjusted to a specific value.

  The operation of the assembly having an oil pump in the first embodiment is now described. In the operation of the engine associated with a relatively low speed, the inner and outer rotors 3 and 4 are rotated in the direction of the arrow X and remain engaged. At this time, the chambers 5 of variable volume undergo a continuous change of one after the other due to this pumping action, the oil of the housing 12 is sucked by the inlet passage 13, the inlet opening 9 and the curved chamber 6 of the oil inlet into the chambers 5 of variable volume and is driven into the first and the second light 10 and 11 oil outlet by the first and the second

bedroom 7 and 8 exit.

  It should be noted that during this operation of the engine at low speed, the amount of oil dispensed

  towards the first and the second light 10 and 11 is practically

  proportionally to the volume of the first and the

  second chamber 7 and 8 of oil outlet The distribution oil

  fog towards the first oil outlet light 10 and that which is distributed towards the second exit light 11

  of oil are hunted and must flow into the pas-

  respective wise 15 and 16 discharge, which are connected in the joining portion of the passages 15 and 16 and which penetrate into the main manifold 17 of supply

oil.

  When the rotation speed of the engine increases, the pressure of the oil discharged into the passages 15 and 16 increases. When, as a result of a continuous increase in the rotational speed of the engine, the pressure of the oil evacuated exceeds predetermined level, the switching valve 19 changes position and communicates the upstream portion 16a of the second passage 16 to the discharge passage 18 and isolates the downstream portion 16b of the upstream portion 16a of the passage 16 In these conditions, the oil discharged to the second passage 16 is forced to return to the passage 13 through the discharge passage 18 Thus, only the oil discharged to the first passage 15 of oil discharge is transmitted to the main manifold 17 and gives

  the amount of lubricating oil needed by the engine.

  Thus, an excessive increase in the pressure in the variable volume chambers of the pump is suppressed and

  undesirable motor energy losses are avoided.

  Given the use of the switching valve 19, the second oil discharge passage 16 and the discharge passage 18 only, the entire construction of the oil pump can be simple, of course.

Small footprint and cost effective.

  Figure 2 of the drawings shows another assembly having an oil pump in a second embodiment

of the present invention.

  As shown in the drawing, in this embodiment, the partitioning structure 14 for separating the first and second oil outlet apertures 10 and 11 has a reduced thickness with respect to the above-mentioned first embodiment. 14a and 14b have respective cavities 14a 'and 14b' which are rotated towards each other. Through these cavities 14a 'and 14b' an undesirable accumulation of pressure in the second lumen 11 oil outlet, which could appear temporarily when the valve 19 performs the switching, is suppressed or at least reduced

at least.

  Thus, as previously described, as the rotational speed of the motor increases to a predetermined value, the switching valve 19 changes position of the represented position to a position in which the upstream portion 16 communicates with the discharge passage 18 and the downstream portion 16b of the passage 16 is isolated from the upstream portion 16a. However, during the switching action of the valve 19, there inevitably occurs a moment during which the downstream portion 16b of the passage 16 and the passage 18 Both at the same time, the pressure of the oil in the upstream portion 16a is increased and thus the second outlet lumen 11 and the second outlet chamber 8 are subjected to pressure. excessively high which tends to increase the amount of energy required

  pump drive and which can cause

  some engine power losses.

  The assembly having the oil pump of the second mode of

  realization comprises the aforementioned structure 14 of partition-

  to overcome this disadvantage More specifically,

  the cavities 14a 'and 14b' are arranged so that the length

  Ll of a chamber 5 of variable volume, formed between the first and second outlet chamber 7 and 8, greater than the distance L 2 between the cavities 14 a 'and 14 b' Thus, when the internal rotors and 3 and 4 take the angular positions shown in the figure, the first and the second output ports 10 and 11 communicate with one another via the

  chamber 5 of variable volume which is placed between them.

  Thus, even at the aforementioned moment, the high pressure of the second exit light 11 can be transmitted to the first exit light 10 by the variable volume chamber 5 and thus the second exit light 11 and the second light exit chamber 8. exit are not under pressure

excessively high.

  Although the switching valve 19 used is

  pilot pressure type in both modes of

  For example, a solenoid valve controlled by a control unit can be used. In this case, the speed of rotation of the oil pump, the pressure of pump discharge and similar parameters are used as information transmitted to the control unit. The oil pump according to the invention is applicable to various hydraulic devices, in addition to a combustion engine.

  internal combustion of the aforementioned type.

  We can note from the description above

  that, in the oil pump according to the invention, when the discharge pressure exceeds a predetermined value, the switching valve 19 changes position to communicate an outlet light 11 with the discharge passage 18 The unwanted excessive increase In addition, in the oil pump of the second embodiment, the pressure rise phenomenon in the variable volume chambers of the pump is eliminated or at least minimized.

  deleted in a more certain way.

  Of course, various modifications may be made by those skilled in the art to assemblies having an oil pump which have just been described as non-limiting examples without departing from the scope of the invention. he

Claims (6)

  1 assembly having an oil pump, characterized in that it comprises: an oil pump which comprises a casing (1) having an inlet lumen (9) and a first and a second outlet lumen (10, 11) , and internal and external toothed rotors (3, 4) arranged in the pump casing so that they delimit between them a series of chambers (5) of variable volume which can be connected to the inlet and outlet ports ( 9, 10, 11), the first outlet lumen being located downstream of the second outlet lumen in the fluid flow direction in the oil pump, and a control device for connecting the first and second lumens (10, 11) when the pressure at the first output light is less than a predetermined value, and to connect the second output light to the input light when the pressure at the first output light is greater than the value predetermined.   2 assembly according to claim 1, characterized in that the control device comprises: a device for delimiting a first passage (15) discharging from the first output light, a device for delimiting a second passage (16) discharge device from the second outlet lumen, a device for delimiting a discharge passage (18) extending from the entrance port, and a switching valve (19) connecting the first and second evacuation passages while isolating the discharge passage when the pressure at the first exit light is less than the predetermined value, and which connects the second exhaust passage to the discharge passage leaving the first exhaust passage when the pressure at the first light output is   greater than the predetermined value.   Assembly according to Claim 2, characterized in that the switching valve (19) is of the type   pilot valve moved by a spring, comprising a pilot pressure chamber constantly connected to the first evacuation passage (15), a spool of which one face is exposed to the pilot pressure chamber, and a spring (19 a) for returning the spool. in the opposite direction to the force produced in the pilot pressure chamber. 4 An assembly according to claim 2, characterized in that it further comprises: a device defining a return passage, one end of which is connected to the inlet lumen (9) and the other end of which is connected to the first passage ( 15) downstream of the portion in which the second exhaust passage is connected to the first exhaust passage, and a pressure adjustment valve (21) disposed in the return passage (22).   Assembly according to claim 1, characterized in that the distance between the first and the second outlet lumen (10, 11) is less than the longitudinal length of a variable volume chamber (5) which takes a position between the first and second and the second light Release.   Assembly according to Claim 5, characterized in that the first and second outlet openings (10, 11) are formed with respective cavities facing one another.   towards the other so that the distance between the first   and the second output light is reduced.   7 The assembly of claim 1, characterized in that the input section of the first output light (10) is greater than that of the second output light (11). An assembly having an oil pump, characterized in that it comprises: a pump casing (1) having an inlet lumen (9) and first and second outlet lumens (10, 11), an inner rotor ( 3) mounted so that it can rotate in the housing, the inner rotor having outer teeth formed integrally thereon, an outer rotor (4) mounted so that it can rotate in the housing and eccentrically surrounds the inner rotor, the outer rotor having internal teeth integral therewith, the inner and outer rotors (3, 4) being engaged by their respective teeth so that they delimit between them a series of chambers (5) of variable volume the first outlet lumen being placed downstream of the second outlet lumen in the fluid flow direction in the oil pump,   a first and a second passage (15, 16) of evacuation   a discharge passage (18), one end of which is connected to the inlet port, and a switching valve (19) which connects the second port of the first and second outlets respectively; evacuation at the first exhaust passage while isolating the discharge passage when the pressure in the first exhaust passage is less than a predetermined value, and which connects the second exhaust passage to the discharge passage, while leaving the first evacuation passage, when the pressure in the first evacuation passage is greater than the predetermined value.  9 assembly according to claim 8, characterized in that the first and the second outlet lumen (10, 11) are formed with respective cavities facing each other so that the large distance between the first and second output light is reduced, this important distance being less than the longitudinal length of a chamber (5) of variable volume which takes a position between the first and the second light (10, 11) output.   An assembly according to claim 8, characterized in that the inlet lumen (9) of the pump casing (1) is exposed to front chambers (5) of variable volume which have just been formed during operation of the pump. pump, the first outlet lumen (10) is exposed to the rear chambers of the variable volume chambers which are about to disappear during operation of the pump, and the second outlet lumen (11) is exposed to specific chambers of variable volume whose volume is about to decrease after they take their maximum volume.