US3254377A

US3254377A - Fluid cooled, lubricated and sealed piston means for casting devices

Info

Publication number: US3254377A
Application number: US282827A
Authority: US
Inventors: Glenn R Morton
Original assignee: Individual
Current assignee: Individual
Priority date: 1963-04-22
Filing date: 1963-04-22
Publication date: 1966-06-07
Anticipated expiration: 1983-06-07

Description

June 7, 1966 G. R. MORTON 3,254,377

FLUID COOLED, LUBRICATED AND SEALED PISTON MEANS FOR CASTING DEVICES Filed April 22, 1963 lzV/f/VER 4259 6. 440670 Is /7405515 5: WORMEAIMfiV/SJ Illa/ 9 VS UIIIECG 31:31:68 f2lII1II UH1C 3,254,377 FLUID COOLED, LUBRICATED AND SEALED PIS- TON MEANS FOR CASTING DEVICES Glenn R. Morton, 7025 Sarpy Ave., Omaha, Nebr. Filed Apr. 22, 1963, Ser. No. 282,827 3 Claims. (Cl. 22-68) This invention relates to casting machines and more particularly to a means for cooling, lubricating and sealing the material injecting means, such as the short piston and cylinder or compression piston and cylinder of a casting device. This is a continuation in part of my application Serial Number 53,704 filed September 2, 1960, now abandoned.

The casting of objects and parts is very old but many apparatus refinements in the art have been made in recent years. Today, it is quite common to produce at least a semi-vacuum condition in the mold cavity prior to the introduction of the molten material. Also, in most such casting equipment, the molten material is pressure forced into the mold cavity by a piston means. The piston may be reciprocatively mounted in a shot cylinder, or it may be in the form of at least a part of one side of the mold cavity as shown in FIGURE 1. However, regardless of the function, or design of the cylinder and piston, much difficulty is experienced in the objectionable heating of the piston, the proper lubricating of the piston, and the leakage of the molten material and even air past the piston.

Therefore, one of the principal objects of my invention is to provide a method of and means for lubricating and cooling the injection and/or compressing piston of a casting device.

More specifically the object of my invention is to surround the reciprocating piston means with a changing mote of fluid such as a lubricating oil.

A still further object of this invention is to provide an oil sealed piston means for casting machines.

Still further objects of my invention are to provide a method of and means for conditioning the piston means of a casting machine that is economical in manufacture and durable in use.

These and other objects will be apparent to those skilled in the art.

My invention consists in the construction, arrangements, and combination, of the various parts of the device, whereby the objects contemplated are attained as hereinafter more fully set forth, specifically pointed out in my claims, and illustrated in the accompanying drawing, in which:

FIGURE 1 is a side sectional view of a casting machine using my piston conditioned means, and

FIGURE 2 is a cross sectional view of the device taken on line 2-2 of FIGURE 1, and more fully illustrates its construction.

In the drawing I have used the numeral to designate one side of a mold block. The second mold block is generally designated by the numeral 11. These two blocks are separable for the purpose of discharging the solidified casting but are detachably held together by any suitable means during the actual casting phase. The adjacent faces of the blocks are cut away to provide, when the blocks are secured together, the mold cavity 12. Communicating with the mold cavity is a conduit 13 adapted to be in communication with a suction producing means (not shown). In the block 11 is formed a relatively large vertical cylinder or passageway 16 communicating with and forming a part of the mold cavity as shown in FIGURE 1. Slidably mounted in this cylindrical portion 16 is a vertical piston ram 17 having its top surface forming at least a portion of the under side of the mold cavity 12. This member 17 may be power reciprocated by any suitable means. In the drawing I show a powered crank shaft 19 and a connecting rod 20 having one end rotatably mounted on the crank arm 19 and its other end hingedly secured to the bottom of the member 17. By this arrangement of parts at least a part of one side or face of the mold cavity will be movable. The numeral 21 designated the molten material inlet conduit communicating with the inside of the cylinder 16 at a point between the extreme movement of the piston member 17 in both directions. Therefore, when the piston member 17 is in a lowered position the conduit 21 will communicate directly with the inside of the cylinder 16 but when the piston 17 is elevated in its sliding movement, the point of communication between the conduit 21 and the cylinder 16 will be closed by the side wall of the member 17. The numeral 22 designates a container having the molten material 23, and into which the conduit 21 extends.

With the two mold sections 10 and 11 closed together and with the piston ram 17 held in a lowered position, the conduit 13 is opened thereby producing a semivacuum within the mold cavity. Due to the minus atmospheric pressure within the mold cavity and the upper end of the cylinder 16, the molten material 23 will flow into the upper end of the cylinder 16 and mold cavity. After a suitable amount of the molten material has entered the mold the conduit 13 is closed and the piston ram 17 is moved upwardly to its maximum elevated position within the cylinder 16 as shown by broken lines in FIGURE 1. After the pressurized casting has cooled, the two mold halves are separated and the casting taken therefrom.

The casting machine thus far disclosed is one example of an apparatus to which I apply my invention and which I will now describe in detail.

As to the piston 17 I have an enlarged head portion 25 and a reduced rear end portion 26. The reduced lower or rear end of the piston slidably extends through a close fitting gasket 27 at the lower or rear end of the cylinder 16, thereby creating a compartment 29 in the lower area of the cylinder and which surrounds the reduced area of the piston below its head 25. In the cylinder wall and embracing the head 25 when the piston is in a lowered position in the cylinder, is a continuous groove or mote 30. When the piston is in an elevated position in the cylinder, this mote groove will be in communication with the compartment 29. The numeral 31 designates an oil supply tank adapted to contain oil or like 32. On top of the tank 31 is a relatively small oil return tank 33. The numeral 35 designates a vertical pipe having one end communicating with the inside of the tank 33 above its inside bottom and its other end communicating with the inside of the tank 31. The top of pipe 35 dwells above the bottom of tank 33. The numeral 36 designates a one-way valve for preventing fluid in the tank 31 from passing directly into the tank 33. A vacuum in tank 33 will normally hold valve 36 closed, but an accumulation of oil in the tank will depress the ball-spring component in the valve and the oil will move into tank 31. The numeral 37 designates a conduit having one end communicating with the inside top of the tank 33 and its other end adapted to be in communication with a Patented June 7, 1966 source of suction (not shown). The numeral 39 designates a solenoid valve imposed in the conduit 37. The numeral 40 designates a conduit having one end communicating with the compartment 29 and its other end communicating with the inside of the tank 33. The numeral 41 designates a conduit having one end communicating with the mote grove 30 and its other end communicating with the inside bottom area of the tank 31. The numeral 42 designates a one-way check valve for preventing liquid from returning from the conduit 41 back into the tank 31. The operation of my device is as follows:

Obviously, the movement and position of the piston may be timed or regulated with the normally closed solenoid valve 39. This can be done in several convenient ways. For example, a micro-switch (not shown) in a normally closed position can be held in an open position by the upper portion of crankshaft 19 as viewed in FIG- URE 1. The micro-switch can be electrically connected to the solenoid valve 39 and thence to a source of electrical energy. Thus, when the top of the crankshaft 19 moves downwardly from the position shown in FIG- URE l, the micro-switch can move to a closed position to cause solenoid valve 39 to become electrically excited and to open. A vacuum will then be pulling through conduit 37, tank 33 and line 40 until the piston head is lowered and the crankshaft 19 once again opens such a micro-switch to close valve 39.

When the piston 17 moves upwardly, the solenoid valve a 39 is opened in the manner described and a vacuum is allowed to pull through conduit 40.as indicated. This initially performs no function until the compartment 29 has moved upwardly to register with mote 30 which serves to connect conduits 40 and 41. This allows the vacuum on conduit 40 to create a suction in conduit 41 (through compartment 29) which opens valve 42 and brings oil from tank 31 into mote- 30 through conduit 41. The oil will thence move from the mote 30 into the compartment 29, and thence through the conduit into tank 33. As soon as the extreme lower end portion 45 of piston 17 moves upwardly through gasket 27, the suction on conduit 41 is broken and no more oil is pulled from tank 31. Similarly, all the oil in conduit 40 is pulled into tank 33 and then only atmospheric air moves into the conduit and moves toward tank 33 and valve 39. No oil will move into the top of pipe 55, until the depth of oil in tank 33 achieves the height of the top of the pipe. Thus, the accumulation of oil in tank 33 permits it to cool before moving into tank 31. In addition, the air being pulled through tank 33 during thisphase of the operation serves to further cool the oil. When the oil reaches a level in tank 33 to fill pipe 35, the weight of the oil will slightly depress the ball and spring in valve 36, and the cooled fluid will then pass by gravity into tank 31. The tank 33 never becomes full enough of fluid to permit fluid to be pulled towards valve 39 through conduit 37. Normally, one cycle of piston 17 will not create a large enough accumulation of fluid in tank 33 to permit oil to flow through pipe 35 into tank 31.

Some oil will remain by adhesion in the mote 30 and will serve as an oil supply to lubricate the piston 17. Also, before the vacuum is broken in the manner described, the piston 17 will be surrounded by an oil bath in compartment 29. It is seen from the foregoing that the coordination of valve 39 with the remaining com ponents of my device is important only if the vacuum being pulled through conduit 37, tank 33 and line is not continuous. For purposes of efliciency of operating the source of the vacuum, it is desirable to close off the vacuum in line 37 by valve 39 at least during part of the cycle. The vacuum must be pulling at the timethat compartment 29 joins conduits 40 and 41, but any arrangement which will close valve 39 or otherwise relieve the vacuum on line 40 after the lower end of the piston 17 breaks the vacuum in compartment 29 will prove satisfactory. As noted above, the pulling of atmospheric air through tank 33 after the vacuum is broken does serve the beneficial result of cooling the oil in the tank. It should be further noted that the pilling of oil from tank 31, through conduit 41, mote 30, compartment 29, conduit 40 and into tank 33 while the vacuum is in effect is an impulse and momentary phenomenon that takes place only once each cycle of piston 17, and which moves only a nominal amount of oil during this brief portion of the cycle.

Some changes may be made in the construction and arrangement of my fluid cooled, lubricated and sealed piston means for casting devices without departing from the real spirit and purpose of my invention, and it is my intention to cover by my claims, any modified forms of structure or use of mechanical equivalents which may be reasonably included within their scope.

I claim:

1. In combination,

a cylinder,

a reciprocating piston in said cylinder,

a recessed portion in said piston to create a compartment between said piston and the interior of said cylinder,

conduits leading to and from the interior of said cylinder,

said compartment having a size to communicate with said conduits at one portion of said pistons reciprocating path in said cylinder,

means operatively secured to said conduits for circulating a fluid into said cylinder from one conduit and withdrawing said fluid therefrom through said other conduit,

said one of said conduits being connected to a vacuum source, the other of said conduits being connected to a source of fluid,

and means on said piston for exposing said compartment to the atmosphere at one stage of its reciprocal movement. a

2. In combination,

a cylinder,

a reciprocating piston in said cylinder,

conduits leading to and from the interior of said cylinder,

one of said conduits being connected to a vacuum source, and the other of said conduits being connected to a source of fluid,

a fluid cooling chamber being imposed in said firstment between said piston and the interior of said cylinder,

conduits leading to and from the interior of said cylinder,

said compartment having :1 size to communicate with said conduits at one portion of said pistons reciprocating path in said cylinder,

said cylinder communicating with a mold cavity between two molded blocks,

and molten liquid intake conduit being in communication with said cylinder.

6 References Cited by the Examiner UNITED STATES PATENTS 543,165 7/1895 Weiss 123192 1,001,306 8/1911 RiX 18418 3,029,752 4/ 1962 Frank 107-17 J. SPENCER OVERHOLSER, Primary Examiner.

R. D. BALDWIN, Assistant Examiner.

Claims

1. IN COMBINATION, A CYLINDRICAL, A RECIRPOCATING PISTON IN SAID CYLINDER, A RECESSED PORTION IN SAID PISTON TO CREATE A COMPARTMENT BETWEEN SAID PISTON AND THE INTERIOR OF SAID CYLINDER, CONDUITS LEADING TO AND FROM THE INTERIOR OF SAID CYLINDER, SAID COMPARTMENT HAVING A SIZE TO COMMUNICATE WITH SAID CONDUITS AT ONE PORTION OF SAID PISTON''S RECIPROCATING PATH IN SAID CYLINDER, MEANS OPERATIVELY SECURED TO SAID CONDUITS FOR CIRCULATING A FLUID INTO SAID CYLINDER FROM ONE CONDUIT AND WITHDRAWING SAID FLUID THEREFROM THROUGH SAID OTHER CONDUIT, SAID ONE OF SAID CONDUITS BEING CONNECTED TO A VACUUM SOURCE, THE OTHER OF SAID CONDUITS BEING CONNECTED TO A SOURCE OF FLUID, AND MEANS ON SAID PISTON FOR EXPOSING SAID COMPARTMENT TO THE ATMOSPHERE AT ONE STAGE OF ITS RECIPROCAL MOVEMENT.