US3921609A

US3921609A - Variable duration hydraulic valve tappet

Info

Publication number: US3921609A
Application number: US498277A
Authority: US
Inventors: James E Rhoads
Original assignee: Individual
Current assignee: Individual
Priority date: 1974-08-16
Filing date: 1974-08-16
Publication date: 1975-11-25
Anticipated expiration: 1992-11-25

Abstract

A hydraulic valve lifter for use in high performance engines to prevent valve overlap at low operating speeds, the lifter having a restricted oil bleed passageway leading to the pressure chamber to prevent the lifter from pumping up to a fully solid condition at low speeds, the passageway being narrow enough to become substantially inoperative at high speeds to produce effectively solid lifter action.

Description

United States Patent 1191 1111 3,921,609 Rhoads 51 Nov. 25, 1975 [54] VARIABLE DURATION HYDRAULIC 2,688,318 9/1954 Voorhies 123/9055 VALVE TAPPET 3,024,709 4/1963 Flick 137/5133 3,142,290 7/1964 Lesher.... 123/9057 Inventor! James Rhoads, La Mesa. h 3,291,107 12/1966 Cornell 123/9055 Assignee: Jack L. y AriL 3,304,925 2/1967 Rhoads 123/9055 [22] Filed: 1974 Primary Examiner-Char1es .I. Myhre 211 App] 49 277 Assistant Examiner-Daniel J. OConnor Attorney, Agent, or Firm-Ralph S. Branscomb 52 US. Cl 123/9055; 123/9057 [51] Int. C1. FOIL 1/14 ABSTRACT [58] Fleld of Search 137/5133, 513.5; A hydraulic valve lifter for use in performance 123/9055 9058 engines to prevent valve overlap at low operating speeds, the lifter having a restricted oil bleed passage- [56] References Clted way leading to the pressure chamber to prevent the N D STATES PATENTS lifter from pumping up to a fully solid condition at low 603,566 5/1898 Kramer 137/5135 speeds, the passageway being narrow enough to be- 672,384 4/ 1901 Marvin 137/5135 come substantially inoperative at high speeds to pro- 2,116,749 5/1938 Daisley 123/9055 duee effe tively solid lifter action. 2,237,854 4/1941 Voorhies... 123/9055 2,272,074 2/1942 Voorhies 123/9055 4 Claims, 7 Drawing Figures US. Patent Nov. 25, 1975 VARIABLE DURATION HYDRAULIC VALVE TAPPET BACKGROUND OF THE INVENTION With conventional types of hydraulic valve lifters, each valve actuating push rod seats in a plunger axially slidable in a lifter body, and the lifter body rides on one lobe of the cam. Oil from the engine lubrication system is introduced under pressure between the body and plunger and at increased engine speeds the valve lifter assembly expands axially to tighten the linkage in the valve actuating train. Many lifters are designed to trap oil in the body chamber and pump up to an effectively solid condition at relatively low speed. However, with high performance cams the valves are timed to have considerable overlap in order to provide for a large flow through the engine. At low speeds this large overlap is not necessary and the engine runs inefficiently, resulting in a loss in low speed horsepower. Basically, increasing the valve lash will shorten valve open duration and reduce overlap, since more crankshaft rotation is necessary to overcome the lash in the valve train.

This will result in an improvement in low speed performance. However, excessive lash causes considerable noise and wear at idling and low speeds. Decreasing lash, as by tightening or pumping up the lifters, will lengthen valve duration and improve high speed performance.

Another hydraulic valve lifter invented by applicant and described in U.S. Pat. No. 3,304,925, permits oil bleed from the pressure chamber to occur at a predetermined minimum speed but prevents bleed at high speeds, causing the desired solid lifter action to occur. However, it has been foundthat under certain circumstances it is not necessary to prevent oil bleed below a minimum speed and there are reasons for designing the lifter to allow bleeding at low as well as intermediate speeds.

SUMMARY OF THE INVENTION The valve lifter described herein is designed to provide favorable characteristics over the entire speed rangev At low and intermediate speeds a closely controlled oil leak in the pressure chamber is permitted to prevent pumping up to a fully solid condition. At high speeds the motion is so rapid that the oil can no longer escape to any degree through the restricted leak path and the lifter becomes effectively solid.

This is accomplished by providing a bleed passageway to the pressure chamber which is continually open at all operating speeds and may be manifested in several different configurations, including a flat ground on the side of the plunger and a groove, port, or other irregularity provided in the check valve or valve seating at the bottom of the piston to prevent the valve from completely sealing.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view, taken axially along a valve lifter, showing the mechanism in the valve closed position;

FIG. 2 is a similar sectional view with the mechanism in the valve open position;

FIG. 3 is a perspective view of the plunger;

FIG. 4 is a sectional view, similar to a portion of FIG. 1, showing a wafer type check valve;

2 FIG. 5 is an enlarged perspective view of the wafer check valve element;

FIG. 6 is a perspective view of an alternative wafer element; and

FIG. 7 is a perspective view of a further wafer element.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 and 2 show the valve lifter l0 axially slidably mounted in a bore 12 in a portion of the engine head casting 16. A single valve is shown, there being one lifter for each valve in the engine, with each lifter operated by a lobe 18 on a comshaft 20. In the head 16 is an oil gallery 22 with a supply duct 24 leading to bore 12 to supply oil to the lifter from the pressure side of the engine oil system.

Valve lifter 10 comprises a cylindrical body 26 having a closed lower end 28, and axially slidable within the body is a hollow cylindrical plunger 30. In the upper end of plunger 30 is a cup 32 in which is seated the end ofa push rod 34, the push rod being coupled to a conventional rocker arm and valve, not shown. Plunger 30 is retained by a snap ring 36 in a groove 38 within the upper end of body 26. Body 26 has an external peripheral collecting channel 40 which registers with the supply duct 24. A port 42 communicates from channel 40 to the interior of body 26 and plunger 30 has a peripheral channel 44 which registers with port 42 at all times. From channel 44 a port 46 leads to the interior of plunger 30, so that oil is continuously admitted into the inner chamber 48 of the plunger from the oil gallery regardless of any rotational or axial displacement experienced by the lifter components.

At the lower end of plunger 30 is a small outlet 50, the lower end of which is closed by a check valve 52 having a sealing element 53 held in place against the seating 54 by a seating spring 55, the spring and valve being held in place by a perforated retaining cage 56. The space between plunger 30 and the lower end of body 26 comprises a pressure chamber 58 and in this chamber is a return spring 60 which biases the plunger upwardly out of the body, until stopped by the snap ring 36. In normal assembly the plunger 30 is pressed down against return spring 60 by the push rod 34, I

which is loaded by the much stronger valve spring, not shown.

The structure thus far described is conventional and representative of hydraulic valve lifters, which may vary somewhat in porting and check valve arrangements. In operation the plunger chamber 48 receives oil under pressure at each upward stroke of the lifter, the oil being forced down through check valve 52 into pressure chamber 58. At low pressure the plunger rides low in the body and is raised by increasing pressure to tighten the valve train. With no return leakage, or only that which may occur through the normal sliding clearance of plunger 30 in the body 26, the oil in chamber 58 is pumped up rapidly and the lifter becomes effectively solid.

The novel action is provided by a bleed passageway providing continuous communication between the pressure chamber 58 and the oil collecting channel 40. The valve lifter described in the previously mentioned U.S. Pat. No. 3,304,925 also provided a bleed passageway but it was not continuously open, being blocked at low speeds. The continuously open passageway can be incorporated in several different ways which would not be possible in the earlier unit, and one form, in which the passageway includes a bleed duct 62 comprising a flat 64 ground along the outer surface of the plunger from the bottom to the channel 44, is simply an extension of the earlier bleed duct and has the advantage of being easier to mill. Body 26 has an internal return channel 66 extending axially to port 42, and since the channel 66 is in constant communication with the channel 44, there is provided at all times a complete passageway from the pressure chamber 58 to the chan nel 66 and to the external collecting channel 40 and thus to the oil gallery 22.

In operation, as the engine speed increases and the oil pressure rises, the lifter will attempt to pump up. However, since oil can leak from the pressure chamber through the bleed passageway, the pumping up will be retarded. As higher engine speeds are achieved, the resistance of the bleed passageway effectively increases since it is too narrow to pass oil in quantity at high speeds, resulting in the gradual pumping up of the lifters with increased engine speed and effectively solid lifter at high speeds.

It has been found in tests that a flat portion 64 ground off to provide a bleed duct having a depth on the order of from two to five thousandths of an inch will provide the required characteristics in the engine ofa passenger automobile. The exact amount will dependon the normal oil pressure in the engine, the cam design with regard to valve timing and duration and to the overall performance range of the engine. In racing engines it would be possible to enlarge the bleed duct to as much as ten or fifteen thousandths of an inch. An oil bleed of this magnitude would result in considerable valve lash and noise at idle speeds, but this can be tolerated in a racing engine.

The crucial requsite for proper operation of the lifter resides in the continually open bleed passageway between the pressure chamber and the collecting channel 40 so the pressure chamber can bleed to the oil gallery 22. Other groove configu'rationsin the plunger surface, and even in the internal surface of the cylinder body, are conceivable which would produce the desired result. In addition, the check valve 52 could be altered slightly so that it cannot completely seal, whereby a bleed pathway would be defined through the valve, plunger chamber 48; and through the

ports

42 and 46. This could be accomplished in numerous ways, such as scoring or etching the ball 53 if a ball check valve is used, providing a notch 68 or other irregularity in the valve seating 54 as shown in FIG. 4.

Three other means. of altering the check valve are shown as examples in FIGS. 5-7, in which a wafer check valve is used rather than a ball check valve. The wafer sealing element 53 is apertured 70 in FIG. 5 and provided with radial and diametric grooves of insufficient size to sustain oil bleed at high engine speed on its sealing surface at 72 and 74 in FIGS. 6 and 7 respectively, any of which produce the obvious result of rendering a complete seal of the check valve impossible and providing a proper bleed passageway from the pressure chamber 58 to the collecting channel 40.

The various arrangements described herein are adaptable to a variety of engines and can be incorporated into many existing types of valve lifter, without requiring any changes in the engines. In fact existing lifters already in use can be modified in accordance with this disclosure. It is understood that minor variation from the form of the invention disclosed herein may be made without departure from the spirit and scope of the invention, and that the specification and drawings are to be considered as merely illustrative rather than limiting.

I claim:

1. In a hydraulic valve lifter having a hollow cylindriat least one restricted oil bleed passageway providing, at all points of operation of the hydraulic.

valve lifter, continuous communication between said pressure chamber and said collecting channel; said oil bleed passageway being substantially dimensionally independent of temperature induced volumetric changes in said valve lifter;

the cross sectional area of at least a portion of said I bleed passageway being insufficient to sustain .oil bleed beyond a predetermined flow rate at high engine speed. 2. Structure according to claim 1 wherein said body has an internal channel communicating withthe first mentioned port and said bleed passageway includes a duct defined by a flat portion on the outer surface of said plunger extending from said pressure chamber. to said internal channel.

3. Structure according to claim 1 wherein said plunger has an enternal peripheral channelcommunieating with said parts and said bleed passageway in,-

cludes a duct defined by a flat portion on the outside of I said plunger extending from said pressure chamber. to

said peripheral channel.

.4. Structure according to claim 1 wherein said has a seating and a wafer sealing element therefrom having a groove traversing at least a portion of the seating side thereof, whereby the passageway provided from said pressure chamber to the interiorof said chamber through said groove comprises a portion of said bleed passageway.

valve

Claims

1. In a hydraulic valve lifter having a hollow cylindrical body with a closed lower end for engagement with a cam; a hollow cylindrical plunger axially slidable in said body and enclosing a pressure chamber in the lower end of the body; an external collecting channel on said body to receive oil from a pressurized source; a port opening into said body from said channel; a port in said plunger communicating with said first mentioned port to admit oil into the plunger; and a one-way valve in said plunger opening into said pressure chamber: an improvement comprising: at least one restricted oil bleed passageway providing, at all points of operation of the hydraulic valve lifter, continuous communication between said pressure chamber and said collecting channel; said oil bleed passageway being substantially dimensionally independent of temperature induced volumetric changes in said valve lifter; the cross sectional area of at least a portion of said bleed passageway being insufficient to sustain oil bleed beyond a predetermined flow rate at high engine speed.

2. Structure according to claim 1 wherein said body has an internal channel communicating with the first mentioned port and said bleed passageway includes a duct defined by a flat portion on the outer surface of said plunger extending from said pressure chamber to said internal channel.

3. Structure according to claim 1 wherein said plunger has an enternal peripheral channel communicating with said parts and said bleed passageway includes a duct defined by a flat portion on the outside of said plunger extending from said pressure chamber to said peripheral channel.

4. Structure according to claim 1 wherein said valve has a seating and a wafer sealing element therefrom having a groove traversing at least a portion of the seating side thereof, whereby the passageway provided from said pressure chamber to the interior of said chamber through said groove comprises a portion of said bleed passageway.