JP6414150B2 - Engine oil supply device - Google Patents

Description

  The present invention relates to an engine oil supply apparatus.

  In the engine, the oil stored in the oil pan is supplied to the engine oil request section by a pump. In Patent Document 1, in order to efficiently separate the fuel contained in the oil, the oil pan is partitioned into the first chamber and the second chamber, and the oil containing a large amount of fuel mixed in the engine piston is lubricated by the guide plate. It is described that the fuel component in the oil is vaporized in the first chamber. After the vaporization of the fuel component, the first chamber and the second chamber are brought into communication with each other, and the oil with the reduced fuel component is introduced into the second chamber, and the oil is supplied from the second chamber to the engine oil request portion by a pump. Has been. Patent Document 1 also describes that the oil in the first chamber is sent to the second chamber by a pump.

  Further, as a hydraulic drive type variable valve mechanism for an engine, for example, a mechanism for converting a cam driving force into a hydraulic pressure and driving an intake valve and an exhaust valve with the hydraulic pressure as described in Patent Document 2 is known. ing. According to this valve operating mechanism, the valve timing and the valve lift amount can be changed by appropriately relieving the hydraulic pressure generated as the cam rotates.

JP 2010-084536 A JP 2009-121481 A

  In the above hydraulic drive type variable valve mechanism, when bubbles are mixed into oil for generating hydraulic pressure, the valve lift amount and valve timing are shifted, and the desired valve opening / closing characteristics cannot be obtained. Normally, oil is supplied to the valve mechanism from an oil pan attached to the lower part of the cylinder block. The main factor for mixing bubbles in the oil is that the oil collides with the counterweight rotating on the crankshaft in the middle of dropping from each part of the engine to the oil pan. When oil collides with the counterweight and is bounced up, air is caught in the oil and bubbles are mixed.

  On the other hand, it is conceivable to separate the oil supply system for the oil demanding part of the engine and the oil supply system for the valve operating mechanism. That is, the oil pan is divided into a first oil storage part and a second oil storage part, and separately from the first oil pump that supplies the oil in the first oil storage part to the oil request part, A second oil pump for supplying oil to the valve operating mechanism is provided, and a dedicated return oil passage for returning the oil supplied to the valve operating mechanism to the second oil reservoir is provided. In this way, it is possible to avoid supplying oil mixed with bubbles to the valve mechanism.

  On the other hand, when the number of oil supply systems is two as described above, oil cannot be supplied to the valve operating mechanism when the second oil pump cannot be operated due to a failure or the like. On the other hand, when the second oil pump does not operate, a part of the oil supplied from the first oil storage unit to the oil request unit by the first oil pump is supplied to the valve mechanism. Can be considered.

  However, if this is done, all of the oil supplied to the valve operating mechanism returns to the second oil reservoir through the dedicated return oil passage, so that the oil in the first oil reservoir gradually decreases, and the engine It will interfere with the oil supply to the oil demanding section.

  Therefore, the present invention hinders the supply of oil to the oil demanding portion of the engine by the first oil pump when the second oil pump that supplies oil free of bubbles to the valve operating mechanism is inoperative. The oil can be supplied to the valve mechanism without any trouble.

  In order to solve the above-mentioned problems, the present invention has two oil supply systems as described above, and when the second oil pump is not in operation, the oil in the first oil reservoir is transferred by the first oil pump. Further, the oil that has returned from the valve operating mechanism to the second oil storage section overflows into the first oil storage section.

The engine oil supply device disclosed herein is
An intake valve configured to be able to open and close the intake port provided in the cylinder;
An exhaust valve configured to open and close an exhaust port provided in the cylinder;
An oil supply apparatus according to an engine comprising a hydraulically driven variable valve mechanism configured to be capable of operating an opening / closing operation of at least one of the intake valve and the exhaust valve,
A first oil pump for supplying oil to a first oil demanding part of the engine;
A second oil pump for supplying oil to a second oil requesting unit including the hydraulically driven variable valve mechanism other than the first oil requesting unit;
A first oil reservoir as an oil supply source for the first oil pump;
A second oil reservoir as an oil supply source for the second oil pump provided separately from the first oil reservoir;
A return oil path for returning the oil supplied to the second oil request section to the second oil storage section so as not to mix with oil returning from the first oil request section to the first oil storage section;
An oil passage that allows a part of the oil discharged from the first oil pump to be supplied to the second oil request unit when the second oil pump is not operated;
The first oil reservoir and the second oil reservoir are provided by partitioning the inside of a common oil pan,
The second oil storage part is provided with an overflow part that causes oil exceeding a predetermined storage amount from the second oil storage part to flow out to the first oil storage part ,
The oil pan includes a bottom wall, a peripheral wall, and a partition wall that rises from the bottom wall and partitions the first oil storage part and the second oil storage part,
An oil drain hole for the second oil reservoir is provided in the lower part of the peripheral wall of the oil pan,
The first oil reservoir has an extension extending from the lower part of the partition toward the oil drain hole for the second oil reservoir, and an oil drain hole for the second oil reservoir at the tip of the extension An oil drain hole for the first oil reservoir facing the
A common drain bolt is fitted to both the oil drain hole for the first oil reservoir and the oil drain hole for the second oil reservoir .

  According to this oil supply device, the oil supplied from the second oil storage unit to the second oil request unit returns to the second oil storage unit through the return oil passage, and the first oil storage unit from the first oil request unit. It does not mix with oil mixed with bubbles returning to the section. Therefore, it is possible to avoid the supply of bubbles with oil to the hydraulically driven variable valve mechanism of the second oil request section by driving the second oil pump, and to open and close the intake valve and the exhaust valve with the desired opening and closing characteristics. This is advantageous, and it is possible to suppress a decrease in fuel consumption performance of the engine.

  When the second oil pump is not operated due to a failure or the like, a part of the oil discharged from the first oil pump is supplied to the valve mechanism of the second oil request unit. It will be possible to avoid disturbing driving.

  Then, when the oil in the first oil reservoir is supplied to the valve operating mechanism by the first oil pump, the oil returns to the second oil reservoir through the return oil passage. In the second oil reservoir, While the oil increases, the oil decreases in the first oil reservoir. However, when the oil storage amount of the second oil storage part exceeds the predetermined storage amount, the excess oil flows out to the first oil storage part by the overflow part. Therefore, the oil in the first oil reservoir is not excessively reduced, and the supply of oil to the first oil requester of the engine is prevented from being hindered. In addition, since a common drain bolt is provided in both the first and second oil reservoirs, oil can be extracted from both oil reservoirs by operating one drain bolt in the oil change. The oil change work becomes simple.

  In a preferred embodiment, the oil outlet of the overflow portion opens at the center of the oil pan.

  According to this, even if the oil in the first oil storage part of the oil pan flows when the vehicle travels on an inclined road or turns, the oil level is not greatly changed even if the oil level is inclined. Therefore, it is advantageous for preventing the oil in the first oil storage part from flowing into the second oil storage part from the oil outlet of the overflow part.

  In a preferred embodiment, the oil outlet of the overflow part opens at a position higher than the oil level of the first oil storage part when the engine is stopped.

  When the engine is stopped, the oil returns from the first oil request section to the first oil storage section, so that the oil level of the first oil storage section becomes high. On the other hand, since the oil outlet of the overflow portion opens at a position higher than the oil level of the first oil reservoir when the engine is stopped, the oil in the first oil reservoir is removed from the oil outlet. It does not flow into the second oil reservoir.

  In preferable embodiment, the said overflow part is provided in the upper wall part of the said 2nd oil storage part. According to this, oil does not flow out from the overflow portion until the second oil storage portion is filled with oil. Therefore, it is possible to avoid the oil in the second oil reservoir flowing out unnecessarily and decreasing when the first and second oil pumps are operated.

In a preferred embodiment, the oil pan, the bottom wall, and the peripheral wall, the integrally molded article formed an the bulkhead oil comprising a pan body portion, of the second oil reservoir to the oil pan main body section The upper wall portion is fixed.

According to this, since the partition wall that rises from the bottom wall of the oil pan functions as a so-called reinforcing rib, the rigidity of the oil pan main body can be improved, which is advantageous for preventing the oil pan from resonating with engine vibrations and thus suppressing noise. Become. In addition, since the oil in the first oil reservoir is prevented from flowing and being biased when the vehicle is traveling on a ramp or turning, the oil suction port related to the first oil pump is prevented from flowing in the first oil reservoir. This is advantageous in avoiding exposure from oil. Then, since the upper wall portion of the second oil storage portion is separated from the oil pan main body portion, it is easy to provide the overflow portion on the upper wall portion.

  The overflow part can also be formed by opening an oil outlet on the wall forming the second oil storage part, but in a preferred embodiment, the overflow part rises from the upper wall part and has oil at the upper end. It is composed of a straight pipe with an open outlet.

  According to this, while it becomes easy to flow out the oil of a 2nd oil storage part smoothly, it becomes advantageous to the inflow prevention of the oil from a 1st oil storage part to a 2nd oil storage part. Further, even when oil mixed with air bubbles flows into the second oil reservoir, the overflow portion can easily function as an air vent pipe, and oil with a small amount of air bubbles can be supplied to the second oil requesting portion. Will be advantageous.

  In a preferred embodiment, a bearing for receiving a crank journal of the crankshaft of the engine is provided above the oil pan, and an oil outlet of the overflow portion opens directly below the bearing.

  According to this, even if the oil mixed with bubbles due to collision with the counterweight of the crankshaft falls toward the oil pan, the mixed oil enters the second oil reservoir from the oil outlet of the overflow portion. Is obstructed by the bearing. Therefore, it is advantageous for preventing air bubbles from being mixed into the oil in the second oil reservoir.

According to the present invention, a first oil pump that supplies oil to a first oil request portion of an engine and a second oil pump that supplies oil to a second oil request portion including a hydraulically driven variable valve mechanism are provided. The first oil storage part for the first oil pump and the second oil storage part for the second oil pump are provided in the oil pan so that the oil returning from the second oil request part to the second oil storage part is the first. The oil returned from the first oil request unit to the first oil storage unit is not mixed, and a part of the oil discharged from the first oil pump is supplied to the second oil request unit when the second oil pump is not operated. Thus, since oil exceeding a predetermined storage amount is allowed to flow out from the second oil storage portion to the first oil storage portion, oil mixed with bubbles may be supplied to the hydraulically driven variable valve mechanism. Therefore, it is advantageous to open and close the intake valve and exhaust valve with the desired opening and closing characteristics, and the oil is hydraulically driven by the first oil pump even when the second oil pump is not operating. Since it can be supplied to the mechanism, it is possible to avoid hindering the operation of the engine, and even in that case, the oil in the first oil reservoir is prevented from being excessively reduced. It can be avoided that the oil supply to the oil demanding section is hindered. In addition, the oil pan is provided with a partition that rises from the bottom wall and partitions the first oil storage portion and the second oil storage portion, and an oil drain hole for the second oil storage portion is provided in a lower portion of the peripheral wall of the oil pan. The first oil reservoir has an extension extending from the lower portion of the partition toward the oil drain hole for the second oil reservoir, and an oil drain hole for the second oil reservoir at the tip of the extension. Since the oil drain hole for the first oil reservoir facing each other is provided, and a common drain bolt is used for the oil drain hole for the first oil reservoir and the oil drain hole for the second oil reservoir , In the oil change, the oil can be drained from both oil reservoirs by operating one drain bolt, so that the oil change operation is simplified.

The front view of an engine. The figure which shows the structure of a hydraulic drive type variable valve mechanism. The figure which shows the structure of an oil supply apparatus. The perspective view of an oil pan. The top view of an oil pan. FIG. 6 is a sectional view taken along line VI-VI in FIG. 5. Sectional drawing of an oil supply part. VIII-VIII sectional view taken on the line of FIG. The perspective view which shows the state which attached the oil pan to the lower block of a cylinder block. The longitudinal cross-sectional view of the same state. The top view of the same state.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The following description of the preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its application, or its use.

  An engine 1 according to the embodiment shown in FIG. 1 is a multi-cylinder engine mounted on a vehicle, and is a cylinder block 3 provided with a plurality of cylinders 2 (only one cylinder is shown in FIG. In the embodiment, four cylinders are provided in series), a cylinder head 4, and an oil pan 5 that is attached to a lower portion of the cylinder block 3 and stores oil. A piston 8 connected to the crankshaft 7 via a connecting rod 6 is fitted into each cylinder 2 so as to be able to reciprocate. A counterweight 9 is provided on the crankshaft 7. An engine combustion chamber 10 is defined by the cylinder 2, the cylinder head 4 and the piston 8.

  The cylinder head 4 is provided with an intake port 11 and an exhaust port 12 that open to the combustion chamber 10. The intake port 11 and the exhaust port 12 are provided with an intake valve 13 and an exhaust valve 14 that open and close the intake and exhaust ports on the combustion chamber 10 side. The intake valve 13 and the exhaust valve 14 are urged by a return spring (reference numeral 19 in FIG. 2) in a direction to close the opening. When the intake valve 13 and the exhaust valve 14 each enter the combustion chamber 10 against the urging force of the return spring, the opening is opened. An intake passage 16 and an exhaust passage 17 each having a throttle valve 15 are connected to each of the intake port 11 and the exhaust port 12. A downstream side of the intake passage 16 from the throttle valve 15 and the cylinder head space are connected by a blow-by gas passage 18.

  The cylinder head 4 is provided with a hydraulically driven variable valve opening / closing mechanism 40 as a hydraulically driven variable valve mechanism for opening / closing the intake valve 13 and the exhaust valve 14 of each cylinder 2.

<Regarding the hydraulically driven variable valve opening / closing mechanism 40>
As shown in FIG. 2, the hydraulically driven variable valve opening / closing mechanism 40 transmits the power of the cam 44 that is rotationally driven by the crankshaft 7 to the intake valve 13 or the exhaust valve 14 (hereinafter, “ The intake valve 13 or the like "is transmitted to the intake valve 13 or the like. For this purpose, the valve opening / closing mechanism 40 includes an oil supply passage 41, an oil storage chamber 42, a hydraulic control valve 43, a first transmission chamber 45, and a second transmission chamber 46. According to the valve opening / closing mechanism 40, continuous fine control of the opening / closing timing and the lift amount of the intake valve 13 and the like is possible by adjusting the hydraulic pressure.

  The oil supply passage 41 includes oil passages 41a, 41b, and 41c branched in three directions. A hydraulic control valve 43 is provided at the intersection of the oil passages 41a to 41c. The oil passage 41 a is connected to the oil storage chamber 42. The oil passage 41b is connected to a second transmission chamber 46 for transmitting hydraulic pressure to the intake valve 13 and the like. The oil passage 41c is connected to the first transmission chamber 45 for generating hydraulic pressure.

  The oil storage chamber 42 stores oil to be supplied to the main body (the first and second transmission chambers 45 and 46 and the oil passages 41b and 41c) of the valve opening / closing mechanism 40. The replenishment oil is supplied to the oil storage chamber 42 through a second oil supply passage 33 described later provided with a check valve 50.

  The first transmission chamber 45 is formed in a cylinder shape, and a piston 47 is inserted therein. A rod 47 a coupled to the piston 47 is in contact with the rocker arm 49. As the cam 44 rotates, the piston 47 is pushed through the rocker arm 49 and the rod 47a. As a result, hydraulic pressure for transmitting the driving force by the cam 44 to the intake valve 13 or the like is generated in the first transmission chamber 45.

  The second transmission chamber 46 is formed in a cylinder shape, and a piston 52 is inserted therein. A stem such as an intake valve 13 is coupled to the piston 52. The hydraulic pressure generated in the first transmission chamber 45 is transmitted to the second transmission chamber 46 through the oil passage 41c, the hydraulic control valve 43, and the oil passage 41b. The piston 52 is pushed by this hydraulic pressure, and the intake valve 13 and the like are lifted.

  The hydraulic control valve 43 is electrically connected to a control unit 100 described later. The hydraulic control valve 43 operates according to a control signal from the control unit 100 in a closed state where the oil path 41a and the oil path 41b are blocked and an open state where the oil path 41a and the oil path 41b are communicated. To do.

  When the hydraulic control valve 43 is closed, the power transmitted from the cam 44 to the first transmission chamber 45 is hydraulically transmitted to the second transmission chamber 46 through the oil passages 41b and 41c, and the intake valve 13 and the like are opened and closed. To do. When the hydraulic control valve 43 is opened, the oil in the second transmission chamber 46 is relieved to the oil storage chamber 42 through the oil passages 41a and 41b, so that the hydraulic pressure is not transmitted from the first transmission chamber 45 to the second transmission chamber 46. . Therefore, the intake valve 13 or the like is in a state where the opening of the intake port 11 or the like is closed by the return spring.

  Here, in the valve opening / closing mechanism 40, for example, between the cylinder constituting the first transmission chamber 45 and the rod 47a of the piston 47, between the cylinder constituting the second transmission chamber 46 and the rod of the piston 52, etc. There is a gap. Therefore, oil leaks from the gap not only during operation of the engine 1 but also when the engine 1 is stopped. Thus, when the operating oil between the first transmission chamber 45 and the second transmission chamber 46 of the valve opening / closing mechanism 40 decreases, the desired valve opening / closing characteristics cannot be obtained.

  In view of this, the oil storage chamber 42 is provided in the valve opening / closing mechanism 40, and oil is supplied from the oil storage chamber 42 to the main body of the valve opening / closing mechanism 40 by the gravity supply method as operating oil. The oil storage chamber 42 is a cylinder head that is positioned higher than the main body of the valve opening / closing mechanism 40 when the engine 1 is disposed in the vehicle in order to reliably supply oil to the main body of the valve opening / closing mechanism 40. 4 is provided. An air / oil drain hole 48 is provided in the upper part of the oil reservoir chamber 42 for draining excess oil generated by opening the air or the hydraulic control valve 43. An oil passage 51 is connected to the air / oil drain hole 48. The downstream end of the oil passage 51 opens into the cylinder head space above the cam 44 and the rocker arm 49 so that surplus oil can be supplied to the cam 44 and the rocker arm 49 as lubricating oil.

  Oil mist generated in the cylinder head space is introduced into the intake passage 16 by the blow-by gas passage 18 shown in FIG.

<About oil supply device>
Next, an oil supply device for the engine 1 provided with the hydraulically driven variable valve opening / closing mechanism 40 will be described.

  As shown in FIG. 3, the oil supply device includes a first oil pump 21 that supplies oil to the first oil request unit 20 </ b> A of the engine 1 and a second oil that supplies oil to the second oil request unit 20 </ b> B of the engine 1. And a pump 22. The first oil pump 21 is a positive displacement variable displacement mechanical oil pump that is driven by the crankshaft 7, and supplies oil to the first oil request unit 20 </ b> A through the first oil supply passage 26. The second oil pump 22 is an electric oil pump that is driven by electric power supplied from the battery of the vehicle, and supplies oil to the second oil request unit 20 </ b> B through the second oil supply passage 33. The first oil passage 26 and the second oil passage 33, that is, the first oil pump 21 and the second oil pump 22 are provided in parallel.

  The first oil requesting unit 20A is an engine lubrication requesting unit, a cooling requesting unit, and / or a hydraulic device, and is supplied with oil through a head gallery, an oil jet passage, a main gallery, and the like. For example, the oil sent to the head gallery is supplied to a cam journal or the like, and then received by the upper deck of the cylinder head 4 and falls to the oil pan 5. The oil sent to the oil jet passage is ejected from the oil jet to the piston sliding portion and falls to the oil pan 5. The lubricating oil sent to the main gallery of the cylinder block 3 is supplied to the connecting rod bearing or the like from the journal of the crankshaft 7 and the oil hole in the shaft, and falls to the oil pan 5.

  The second oil request unit 20B is an oil request unit including the valve opening / closing mechanism 40 other than the first oil request unit 20A, and the oil supplied to the second oil request unit 20B is supplied to the first oil request unit 20A. The oil is received at a location different from the oil, for example, a region provided by partitioning the inside of the upper deck of the cylinder head 4, passes through the return oil passage 37, and is returned to the second oil reservoir 24 described later. In the present embodiment, the oil discharged from the second oil pump 22 is specifically supplied to the oil storage chamber 42 of the valve opening / closing mechanism 40.

  The oil pan 5 includes a first oil reservoir 23 that is an oil supply source of the first oil pump 21 and an oil supply source dedicated to the second oil pump 22, in other words, an oil supply source dedicated to the valve opening / closing mechanism 40. A second oil reservoir 24 is provided. An oil strainer 25 of the first oil pump 21 is provided in the first oil reservoir 23. The first oil pump 21, the oil filter 27, and the oil cooler 28 are provided in this order from the upstream side to the downstream side in the first oil supply passage 26 extending from the oil strainer 25 to the first oil requesting portion 20A. . The oil cooler 28 is appropriately provided as necessary.

  The first oil supply passage 26 is provided with a linear solenoid pressure control valve 29 that controls the discharge pressure of the first oil pump 21 and a first hydraulic sensor 30 that detects the oil pressure downstream of the oil cooler 28. ing. The pressure control valve 29 controls the discharge pressure of the first oil pump 21 so that the pressure of the oil supplied to the first oil requesting unit 20A becomes an optimum pressure according to the operating state of the engine 1. . The operation of the pressure control valve 29 is controlled by the control unit 100 based on the engine operating state and the detected pressure of the first hydraulic pressure sensor 30.

  The second oil reservoir 24 is provided with an oil strainer 32 of the second oil pump 22. The second oil pump 22, the oil filter 34, and the oil cooler 35 are provided in this order from the upstream side to the downstream side in the second oil supply passage 33 extending from the oil strainer 32 to the oil storage chamber 42 of the valve opening / closing mechanism 40. It has been. Note that the oil cooler 35 is also provided as necessary as in the oil cooler 28. Here, the second oil supply passage 33 branches on the downstream side thereof and is connected to the oil storage chamber 42 of the valve opening / closing mechanism 40 of each of the intake valve 13 and the exhaust valve 14 of each cylinder 2. The second oil supply passage 33 is provided with a second oil pressure sensor 36 that detects the oil pressure downstream of the oil cooler 35 and upstream of the valve opening / closing mechanism 40. The operation of the second oil pump 22 is controlled by the control unit 100 so as to achieve the desired discharge pressure based on the pressure detected by the second hydraulic sensor 36.

  In addition, the oil supply device returns oil passage 37 that returns oil leaking from the second oil requesting unit 20B (valve opening / closing mechanism 40) to the second oil storage unit 24 separately from the oil that falls through the crankcase 60. It has. The oil leaking from the valve opening / closing mechanism 40 is received by an oil sump partitioned from the region of the upper deck of the cylinder head 4 that receives the oil supplied to the first oil supply unit 20A. The return oil passage 37 extends from the oil reservoir to the second oil reservoir 24 through an oil drain hole dedicated to the oil reservoir that penetrates the inside of the cylinder head 4 and the inside of the cylinder block 3. That is, the return oil passage 37 is configured by a dedicated passage extending from the cylinder head 3 toward the second oil reservoir 24 so that the bubble-containing oil that collides with the counterweight 9 and scatters does not enter the return oil. .

  It should be noted that since the bubble-containing oil does not have to be mixed into the return oil from the second oil request unit 20B (valve opening / closing mechanism 40), the downstream end of the return oil passage 37, that is, the second oil storage unit side end is set to the second end. It is not always necessary to connect directly to the oil reservoir 24.

  The first oil supply passage 26 and the second oil supply passage 33 are connected by an auxiliary oil passage 38 on the downstream side of the respective oil coolers 26 and 35. The auxiliary oil passage 38 allows the inflow of oil from the first oil supply passage 26 to the second oil supply passage 33 using the pressure difference between the oil passages, while the first oil supply from the second oil supply passage 33 is allowed. A check valve 39 for preventing the oil from flowing into the passage 26 is provided. When the oil pressure in the first oil supply passage 26 is higher than the oil pressure in the second oil supply passage 33, the check valve 39 is opened, and oil flows from the first oil supply passage 26 into the second oil supply passage 33. Even when the oil pressure in the second oil supply passage 33 is higher than the oil pressure in the first oil supply passage 26, the check valve 39 prevents the oil from flowing from the second oil supply passage 33 into the first oil supply passage 26. . The second oil request unit 20B (valve opening / closing mechanism 40) has a required oil pressure higher than that of the first oil request unit 20A, and the auxiliary oil passage 38 does not normally enter a communication state. The auxiliary oil passage 38 is the first when the second oil pump 22 fails or when the second oil pump 22 that is electrically driven due to an extremely cold environment cannot be driven, that is, when the second oil pump is not operating. The oil pump 21 is used to supply oil to the second oil request unit 20B.

[About both the first and second oil reservoirs 23, 24]
As shown in FIGS. 4 and 5, the first oil reservoir 23 and the second oil reservoir 24 are provided in the oil pan 5 in a partitioned manner. The second oil pump 22 is attached to the oil pan 5. The first oil reservoir 23 receives oil that drops from each part of the engine 1 (first oil request part 20A) through the crankcase 60 shown in FIG. In FIG. 5, reference numeral 70 denotes an oil level sensor.

  As shown in FIG. 6, the oil pan 5 includes a bottom wall 5a, a peripheral wall 5b, and a partition wall 5c that rises from the bottom wall 5a and partitions the first oil storage portion 23 and the second oil storage portion 24. The oil pan main body part of the integrally molded product is provided. An upper wall portion 24 a that closes the upper surface opening of the second oil storage portion 24 is fixed to the oil pan main body portion. The upper wall portion 24a and the oil pan main body portion are formed separately. The oil pan main body of the present embodiment has a bottom wall 5a, a peripheral wall 5b, and a partition wall 5c that are integrally formed of, for example, an aluminum alloy, and an upper wall 24a is joined to the oil pan main body. A 3D additive manufacturing method can also be adopted for the integral molding. In this case, the upper wall portion 24a may be integrally formed as an oil pan main body portion. The oil pan 5 may be made of resin for weight reduction and oil heat retention performance improvement.

  In the upper wall portion 24a of the second oil reservoir 24, an oil discharge portion 55 having an oil discharge hole 55a connected to the second oil pump 22, an oil return portion 56, 57 having oil return holes 56a, 57b opened, and an oil An overflow part 58 in which the outlet 58a is opened and an oil supply part 59 in which the oil supply port 59a is opened are provided. The second oil supply passage 33 is connected to the oil discharge portion 55, and the return oil passage 37 is connected to the oil return portions 56 and 57.

  As shown in FIG. 6, the overflow part 58 is constituted by a straight pipe rising from the upper wall part 24a, and an oil outlet 58a is opened at the upper end thereof. Here, the oil outlet 58a is disposed so as to be positioned at the center of the oil pan 5 when the oil pan 5 is viewed from above the engine, and the oil level of the first oil reservoir 23 when the engine 1 is stopped. It opens to a position higher than the height.

  As shown in FIG. 7, the oil supply portion 59 is configured such that a float 59 c is accommodated in a cylindrical accommodation portion 59 b that is open at the upper end as an oil supply port 59 a and closed at the lower end. An oil inflow port into the second oil reservoir 24 is opened at the lower part of the peripheral wall of the housing part 59b. During refueling, the float 59c is pushed down by the supply oil pressure, so that the oil enters the second oil reservoir 24. After refueling, the float 59c is lifted so as to be exposed from the oil surface, thereby closing the refueling port 59a.

As shown in the sectional view taken along the line VIII-VIII in FIG. 5, an oil drain hole 61 for the second oil reservoir 24 is provided in the lower part of the peripheral wall 5 b of the oil pan 5. The first oil reservoir 23 has an extension 24b having a small volume extending from the lower part of the partition wall 5c toward the oil drain hole 61 for the second oil reservoir 24 , and the second oil reservoir is provided at the tip of the extension 24b. An oil drain hole 62 for the first oil storage part 23 is provided opposite to the oil drain hole 61 for the part 24 . A common drain bolt 63 is fitted into both the oil drain holes 61 and 62.

  As shown in FIG. 9, the oil pan 5 is fixed to the lower surface of the lower block 3 a of the cylinder block 3. The lower block 3a is provided with a plurality of journal bearings 65 (five since the engine 1 of the present embodiment has four cylinders) for receiving the crank journal of the crankshaft 7. As shown in FIG. 10, the oil outlet 58 a of the overflow portion 58 of the second oil storage portion 24 opens directly below the central journal bearing 65. Therefore, as shown in FIG. 11, when the second oil reservoir 24 is viewed from above, the oil outlet 58 a of the overflow portion 25 is hidden by the central journal bearing 65.

<About the control unit 100>
The control unit 100 is a control device based on a microcomputer, and inputs signals from various sensors or detection means for detecting the operating state of the engine 1, the remaining battery level, the amount of oil stored in the oil storage chamber 42, and the like. A signal input unit, a calculation unit that performs calculation processing related to control, a signal output unit that outputs a control signal to devices to be controlled (hydraulic control valve 43, oil pumps 21, 22, etc.), and a program necessary for control And a storage unit for storing data (such as a hydraulic control map).

  Here, the control unit 100 outputs a control signal so as to always operate with respect to the second oil pump 22 during operation of the engine 1, and operates the valve opening / closing mechanism 40 when the engine 1 is stopped. Therefore, in principle, the operation of the second oil pump 22 is stopped. Even if the operation of the second oil pump 22 is stopped, the engine 1 is started because oil is supplied from the oil storage chamber 42 to the main body of the valve opening / closing mechanism 40 in accordance with oil leakage in the main body. When this happens, the valve opening / closing mechanism 40 operates normally.

  However, if the engine 1 is stopped for a long period of time, as a result of the above replenishment, there is a possibility that the oil in the oil storage chamber 42 runs out and the main body of the valve opening / closing mechanism 40 becomes in an oil shortage state. The oil supply passage 33 may also be in a state where oil has been removed. In that case, even if the second oil pump 22 is activated when the engine 1 is started, the valve opening / closing mechanism 40 is not immediately filled with oil, and it takes time until it normally operates. That is, the startability of the engine is deteriorated.

  Therefore, in the present embodiment, the control unit 100 drives the second oil pump 22 assuming that the oil storage amount in the oil storage chamber 42 has decreased to a predetermined value or less when the engine 1 has been stopped for a predetermined time. Thus, oil is supplied to the oil storage chamber 42.

<Advantages of this embodiment>
The oil discharged from the first oil pump 21 is supplied to the first oil request unit 20A through the first oil supply passage 26. The oil discharged from the second oil pump 22 is supplied to the second oil request unit 20B (valve opening / closing mechanism 40) through the second oil supply passage 33. Since the required oil pressure of the second oil request unit 20B is higher than that of the first oil request unit 20A, the oil discharged from the first oil pump 21 passes through the auxiliary oil passage 38 when both the oil pumps 21 and 22 are operating. It is not sent via the second oil requesting unit 20B. Further, since the oil discharged from the second oil pump 22 is blocked by the check valve 39 of the auxiliary oil passage 38, it is not sent to the first oil request unit 20A.

  The oil sent to the first oil request unit 20 </ b> A falls through the crankcase 60 toward the oil pan 5 and returns to the second oil storage unit 23. The oil sent to the second oil request unit 20 </ b> B returns to the second oil storage unit 24 through the return oil passage 37.

  Bubbles are mixed into the oil falling toward the oil pan 5 due to the collision with the counterweight 9, but the oil mixed with the bubbles is blocked by the upper wall portion 24a of the second oil reservoir 24. 2 Does not enter the oil reservoir 24. The upper wall portion 24a of the second oil reservoir 24 has an oil outlet 58a of the overflow portion 58. The oil outlet 58a opens directly below the journal bearing 65 that receives the crank journal of the crankshaft 7. . Accordingly, the journal bearing 65 prevents the oil mixed with bubbles from entering the oil outlet 58 a of the overflow portion 58.

  As described above, oil that does not substantially contain bubbles returning from the valve opening / closing mechanism 40 side through the return oil passage 37 enters the second oil reservoir 24, and bubbles falling into the oil pan 5 are mixed in. Oil is rarely entered.

  Accordingly, it is possible to avoid the supply of oil mixed with bubbles to the valve opening / closing mechanism 40 side by driving the second oil pump 22. This is advantageous in opening and closing the intake valve 13 and the exhaust valve 14 with the desired opening / closing characteristics. Therefore, according to the engine operating state, CI combustion (compressed self-ignition combustion in which the air-fuel mixture is combusted by self-ignition) and SI combustion (spark ignition combustion in which the air-fuel mixture is ignited by the spark plug and combusted) are switched. In the engine, the internal EGR control by the opening / closing control of the intake valve 13 and the exhaust valve 14 can be performed precisely, and the engine CI combustion region can be easily expanded.

  On the other hand, when the second oil pump 22 is not in operation (when the second oil pump 22 fails or is extremely cold), the oil discharged from the first oil pump 21 passes through the auxiliary oil passage 38 to the second oil request section. 20B (valve opening / closing mechanism 40). Therefore, even if the second oil pump 22 is deactivated, it is possible to avoid hindering the operation of the valve opening / closing mechanism 40 and consequently the operation of the engine.

  When the second oil pump 22 is not in operation, the oil in the first oil reservoir 23 is supplied to the valve opening / closing mechanism 40 by the first oil pump 21, and the oil returns to the second oil reservoir 24 by the return oil passage 37. It will be. For this reason, the oil increases in the second oil reservoir 24, while the oil decreases in the first oil reservoir 23.

  However, when the oil storage amount of the second oil storage unit 24 exceeds a predetermined storage amount, that is, in this example, when the second oil storage unit 24 becomes full, the oil in the second oil storage unit 24 overflows. Outflow from the portion 58 to the first oil storage portion 23. Therefore, the oil in the first oil storage unit 23 is not excessively reduced, and it is possible to avoid a problem in the supply of oil to the first oil request unit 20A (such as lubrication of each part of the engine).

  The overflow part 58 is provided in the upper wall part 24a of the second oil storage part 24, and the oil does not flow out from the overflow part 58 until the second oil storage part 24 is filled with oil. Therefore, it is possible to avoid the oil in the second oil reservoir 24 from flowing out unnecessarily and decreasing when the first and second oil pumps 23 and 24 are operated.

  The oil outlet 58a of the overflow part 58 is opened at a position higher than the oil level of the first oil storage part 23 when the engine 1 is stopped. Therefore, when the engine is stopped, the oil returns from the first oil requesting unit 20A and the oil level of the first oil storage unit 23 becomes higher, but the oil in the first oil storage unit 23 flows from the oil outlet 58a to the second oil storage unit. 24 does not flow.

  In addition, the oil outlet 58 a of the overflow portion 58 is open at the center of the oil pan 5. Therefore, even if the oil in the first oil reservoir 23 flows when the vehicle travels on an inclined road or turns, the oil level inclines from the oil outlet 58a of the overflow portion 58. 2 Inflow into the oil reservoir 24 is avoided.

  The overflow part 58 is constituted by a straight pipe rising from the upper wall part 24a of the second oil storage part 24, and an oil outlet 58a is opened at the upper end thereof. Therefore, the oil in the second oil reservoir 24 can easily flow out smoothly, but it is advantageous for preventing the oil from flowing from the first oil reservoir 23 to the second oil reservoir 24. Further, even when oil in which bubbles are mixed flows into the second oil reservoir 24, the overflow portion 58 can easily function as an air vent pipe, and oil with a small amount of bubbles mixed into the second oil requesting portion 24. It becomes advantageous in supplying.

  Further, in the oil pan 5, the partition wall 5c rising from the oil pan bottom wall 5a serves as a reinforcing rib, so that the rigidity of the oil pan main body is increased, which is advantageous in preventing resonance of the oil pan 5 with respect to engine vibration, and in turn suppressing noise. become. Moreover, it is suppressed by the partition 5c that the oil of the 1st oil storage part 23 flows and is biased at the time of the vehicle running on the ramp or turning. Therefore, the oil strainer 25 of the first oil pump 21 can be prevented from being exposed from the oil in the first oil reservoir 23.

  The upper wall portion 24a of the second oil reservoir 24 is provided with an oil discharge portion 55, oil return portions 56 and 57, an overflow portion 58, and an oil supply portion 59. The upper wall portion 24a is connected to the oil pan body portion. Therefore, it is easy to provide the above-mentioned elements 55 to 59 on the upper wall portion 24a.

  Further, since the oil pan 5 employs a configuration in which the common drain bolt 63 is provided in both the oil storage portions 23, 24, the oil drain portions 23, 24 can be operated by operating one drain bolt 63 in the oil change. Oil can be drained. Therefore, the oil change operation is simplified.

  In the above embodiment, a mechanical oil pump driven by the crankshaft 7 is employed as the first oil pump 21, but an electric oil pump may be employed.

DESCRIPTION OF SYMBOLS 1 Engine 3 Cylinder block 5 Oil pan 5a Bottom wall 5b Perimeter wall 5c Partition 7 Crankshaft 20A 1st oil request | requirement part 20B 2nd oil request | requirement part 21 1st oil pump 22 2nd oil pump 23 1st oil storage part 24 2nd oil Reservoir 24a Upper wall portion 37 Return oil passage 38 Auxiliary oil passage 40 Hydraulic drive variable valve opening / closing mechanism (hydraulic drive variable valve mechanism)
58 Overflow part 58a Oil outlet 60 Crankcase 65 Journal bearing

Claims (7)

An intake valve configured to be able to open and close the intake port provided in the cylinder;
An exhaust valve configured to open and close an exhaust port provided in the cylinder;
A hydraulically driven variable valve mechanism configured to be operable to open and close at least one of the intake valve and the exhaust valve;
An oil supply device for an engine equipped with
A first oil pump for supplying oil to a first oil demanding part of the engine;
A second oil pump for supplying oil to a second oil requesting unit including the hydraulically driven variable valve mechanism other than the first oil requesting unit;
A first oil reservoir as an oil supply source for the first oil pump;
A second oil reservoir as an oil supply source for the second oil pump provided separately from the first oil reservoir;
A return oil path for returning the oil supplied to the second oil request section to the second oil storage section so as not to mix with oil returning from the first oil request section to the first oil storage section;
An oil passage that allows a part of oil discharged from the first oil pump to be supplied to the hydraulically driven variable valve mechanism when the second oil pump is not operated;
The first oil reservoir and the second oil reservoir are provided by partitioning the inside of a common oil pan,
The second oil storage part is provided with an overflow part that causes oil exceeding a predetermined storage amount from the second oil storage part to flow out to the first oil storage part ,
The oil pan includes a bottom wall, a peripheral wall, and a partition wall that rises from the bottom wall and partitions the first oil storage part and the second oil storage part,
An oil drain hole for the second oil reservoir is provided in the lower part of the peripheral wall of the oil pan,
The first oil reservoir has an extension extending from the lower part of the partition toward the oil drain hole for the second oil reservoir, and an oil drain hole for the second oil reservoir at the tip of the extension An oil drain hole for the first oil reservoir facing the
An oil supply device for an engine, wherein a common drain bolt is fitted to both the oil drain hole for the first oil reservoir and the oil drain hole for the second oil reservoir . In claim 1,
An oil supply device for an engine, wherein an oil outlet of the overflow portion is opened at a central portion of the oil pan. In claim 1 or claim 2,
An oil supply apparatus for an engine, wherein the oil outlet of the overflow part opens at a position higher than the oil level of the first oil storage part when the engine is stopped. In any one of Claim 1 thru | or 3,
The engine oil supply device, wherein the overflow portion is provided on an upper wall portion of the second oil storage portion. In claim 4,
The oil pan, and the bottom wall, and the peripheral wall, an oil pan main body of the integrally molded article formed an the bulkhead, the upper wall portion of the second oil reservoir to the oil pan main body section An oil supply device for an engine characterized by being fixed. In claim 4 or claim 5,
The engine oil supply apparatus according to claim 1, wherein the overflow portion is constituted by a straight pipe that rises from the upper wall portion and has an oil outlet opening at an upper end. In claim 6,
A bearing for receiving a crank journal of a crankshaft of the engine is provided above the oil pan, and an oil outlet of the overflow portion opens directly below the bearing. apparatus.

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